LP5569 [TI]
带引擎控制和电荷泵的九通道 I2C RGB LED 驱动器;型号: | LP5569 |
厂家: | TEXAS INSTRUMENTS |
描述: | 带引擎控制和电荷泵的九通道 I2C RGB LED 驱动器 驱动 泵 驱动器 |
文件: | 总93页 (文件大小:2845K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
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LP5569
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
带引擎控制和电荷泵的 LP5569 九通道 I2C RGB LED 驱动器
1 特性
3 说明
•
电源电压范围:2.5V–5.5V
九个高精度电流源
LP5569 器件是一款可编程、易于使用的 9 通道 I2C
LED 驱动器,用于为各种 应用制造灯光效果。LED 驱
动器配备了一个用于存储用户编程的序列的内部
SRAM 存储器,以及三个允许在无处理器控制的情况
下运行的可编程 LED Engines。将处理器置于睡眠模
式时,自主运行可以降低系统功耗。
1
•
–
–
–
每个通道最大 25.5mA
8 位独立的电流控制
12 位 20kHz 内部单独 PWM 控制(无音频噪
声)
•
三个可编程 LED Engines
高效电荷泵支持通过高 VF(甚至通过 2.5V 输入电
压)驱动 LED。LP5569 LED 驱动器可以根据 LED 正
向电压要求自主选择最佳的电荷泵增益,从而在宽工作
电压范围内保持高效率。
–
–
–
独立照明控制(无有源微控制器控制)
在多个器件之间实现同步
SRAM 存储器中具有多达 256 条指令,用于存
储照明图案序列
当 LED 未激活时,LP5569 器件进入省电模式,从而
显著降低空闲电流消耗。灵活的数字接口允许连接多达
八个 LP5569 器件,每个器件在同一系统中具有唯一
的 I2C 从器件地址,从而支持所有器件之间的灯光效果
同步。
–
与 LP5523 和 LP55231 器件兼容的命令集
•
灵活的调光控制
–
–
–
I2C 调光控制
PWM 直接输入调光
PWM 输入频率:100Hz 至 20kHz
•
•
•
•
用于通过低电池电压驱动高 VF LED 的自适应高效
电荷泵控制
器件信息(1)
器件型号
LP5569
封装
WQFN (24)
封装尺寸(标称值)
主增益调节器控制通过仅对一个寄存器进行写入来
对多个 LED 进行调光,从而降低 I2C 总线流量
4.00mm x 4.00mm
(1) 如需了解所有可用封装,请参阅数据表末尾的可订购产品附
录。
2µA 低待机电流,在自动省电模式下为 10µA(当
LED 不活动时)
简化电路原理图
POR、UVLO 和 TSD 保护
CFLY1
1μF
CFLY2
1μF
2 应用
用于以下设备的 LED 照明、指示灯和闪烁光:
C1–
C1+
C2–
C2+
2.5 V to 5.5 V
VIN
VIN
VOUT
PGND
•
•
•
•
•
•
•
•
•
•
智能扬声器
智能家用电器
门铃
COUT
1 μF
CIN
1 μF
VIN
1.8 V
V1P8
LED0
LED1
LED2
电子锁
烟雾探测器
恒温器
SCL
SDA
LED3
LED4
机顶盒
µC
EN/PWM
CLK
智能路由器
蓝牙®耳机
手机
LED5
LED6
LED7
LED8
GPIO/TRIG/INT
ADDR
AGND
Copyright © 2017, Texas Instruments Incorporated
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
English Data Sheet: SNVSAP8
LP5569
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
www.ti.com.cn
目录
8.1 Overview ................................................................. 11
8.2 Functional Block Diagram ....................................... 12
8.3 Feature Description................................................. 13
8.4 Device Functional Modes........................................ 21
8.5 Programming........................................................... 23
8.6 Register Maps......................................................... 38
Application and Implementation ........................ 78
9.1 Application Information............................................ 78
9.2 Typical Applications ................................................ 78
1
2
3
4
5
6
7
特性.......................................................................... 1
应用.......................................................................... 1
说明.......................................................................... 1
修订历史记录 ........................................................... 2
Device Comparison Table..................................... 3
Pin Configuration and Functions......................... 3
Specifications......................................................... 5
7.1 Absolute Maximum Ratings ...................................... 5
7.2 ESD Ratings.............................................................. 5
7.3 Recommended Operating Conditions....................... 5
7.4 Thermal Information.................................................. 5
7.5 Electrical Characteristics........................................... 6
7.6 Charge-Pump Electrical Characteristics ................... 6
7.7 LED Current Sinks Electrical Characteristics............ 7
7.8 Logic Interface Characteristics.................................. 7
7.9 Timing Requirements (EN/PWM).............................. 7
9
10 Power Supply Recommendations ..................... 82
11 Layout................................................................... 83
11.1 Layout Guidelines ................................................. 83
11.2 Layout Example .................................................... 84
12 器件和文档支持 ..................................................... 85
12.1 器件支持 ............................................................... 85
12.2 接收文档更新通知 ................................................. 85
12.3 社区资源................................................................ 85
12.4 商标....................................................................... 85
12.5 静电放电警告......................................................... 85
12.6 Glossary................................................................ 85
13 机械、封装和可订购信息....................................... 85
7.10 Serial-Bus Timing Requirements (SDA, SCL), See
图 1 ............................................................................ 8
7.11 External Clock Timing Requirements (CLK), See 图
2................................................................................ 8
7.12 Typical Characteristics............................................ 9
8
Detailed Description ............................................ 11
4 修订历史记录
Changes from Original (July 2017) to Revision A
Page
•
Added typical curves .............................................................................................................................................................. 9
2
Copyright © 2017, Texas Instruments Incorporated
LP5569
www.ti.com.cn
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
5 Device Comparison Table
PART NUMBER
LP5569
GROUP
I2C SLAVE ADDRESS
32h–35h and 40h (see I2C Slave Addressing)
42h–45h and 40h (see I2C Slave Addressing)
0
1
LP5569A
6 Pin Configuration and Functions
RTW Package
24-Pin WQFN With Exposed Thermal Pad
Top View
C2+
C1+
1
2
3
4
5
6
18
17
16
15
14
13
LED1
LED2
LED3
LED4
LED5
LED6
VIN
Thermal
Pad
AGND
EN/PWM
CLK
Not to scale
Pin Functions
PIN
TYPE(1)
DESCRIPTION
NAME
NO.
I2C slave-address selection pin. See I2C Slave Addressing for more details. This pin
must not be left floating.
ADDR
AGND
C1–
20
I
Analog and digital ground. Connect to PGND, exposed thermal pad, and common
ground plane.
4
24
2
G
A
A
A
A
Negative pin of charge-pump flying capacitor 1. If charge pump is not used, this pin must
be left floating.
Positive pin of charge-pump flying capacitor 1. If charge pump is not used, this pin must
be left floating.
C1+
Negative pin of charge-pump flying capacitor 2. If charge pump is not used, this pin must
be left floating.
C2–
23
1
Positive pin of charge-pump flying capacitor 2. If charge pump is not used, this pin must
be left floating.
C2+
Clock input/output. By default this pin is a clock input. If not used, this pin must be
connected to GND or VIN.
CLK
6
5
I, OD
I
EN/PWM
Chip enable and PWM input pin.
(1) A: analog pin; G: ground pin; P: power pin; I: input pin; OD: open-drain output pin
Copyright © 2017, Texas Instruments Incorporated
3
LP5569
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
www.ti.com.cn
Pin Functions (continued)
PIN
TYPE(1)
DESCRIPTION
NAME
NO.
General-purpose input or open-drain output, or trigger input or open-drain output, or
interrupt open-drain output. This pin function is configured in the I2C registers. By default
this pin is a general-purpose output (open-drain) and can be left floating if not used.
GPIO/TRIG/INT
7
I, OD
LED0
LED1
LED2
LED3
LED4
LED5
LED6
LED7
LED8
19
18
17
16
15
14
13
12
11
A
A
A
A
A
A
A
A
A
LED current sink 0. If not used, this pin can be left floating.
LED current sink 1. If not used, this pin can be left floating.
LED current sink 2. If not used, this pin can be left floating.
LED current sink 3. If not used, this pin can be left floating.
LED current sink 4. If not used, this pin can be left floating.
LED current sink 5. If not used, this pin can be left floating.
LED current sink 6. If not used, this pin can be left floating.
LED current sink 7. If not used, this pin can be left floating.
LED current sink 8. If not used, this pin can be left floating.
Charge-pump power ground. Connect to AGND, exposed thermal pad, and common
ground plane.
PGND
21
G
SCL
SDA
V1P8
VIN
9
8
I
I, OD
P
I2C bus clock line. If not used, this pin must be connected to GND or VIN.
I2C bus data line. If not used, this pin must be connected to GND or VIN.
Input power for digital circuitry.
10
3
P
Input power, a 1-µF capacitor must be connected between PGND and this pin.
Charge-pump output voltage. If charge pump is used, a 1-µF capacitor must be
connected between PGND and this pin. If charge pump is not used or is used in 1×
mode only, the capacitor can be omitted.
VOUT
22
—
A
Must be connected to AGND (pin 4), PGND (pin 21), and common ground plane. See
Layout Example. Must be soldered to achieve appropriate power dissipation and
mechanical reliability.
Exposed thermal
pad
—
4
Copyright © 2017, Texas Instruments Incorporated
LP5569
www.ti.com.cn
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
7 Specifications
7.1 Absolute Maximum Ratings
over operating ambient temperature range (unless otherwise noted)(1)
MIN
MAX
UNIT
Voltage on VIN, CLK, ADDR, EN/PWM, GPIO/TRIG/INT, SCL, SDA,
VOUT(2)
–0.3
6
V
Voltage on LED0 to LED8, C1–, C2–, C1+, C2+
Voltage on V1P8
−0.3
VVIN + 0.3 V with 6 V max.
V
V
−0.3
Internally limited
–40
2
Internally limited
125
Continuous power dissipation
Junction temperature, TJ-MAX
Storage temperature, Tstg
°C
°C
−65
150
(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended
Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
(2) VOUT cannot be forced to a power supply during device shutdown.
7.2 ESD Ratings
VALUE
UNIT
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001(1)
±2500
V(ESD)
Electrostatic discharge
V
Charged-device model (CDM), per JEDEC specification JESD22-
C101(2)
±250
(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
7.3 Recommended Operating Conditions
over operating ambient temperature range (unless otherwise noted)
MIN
MAX
5.5
UNIT
Input voltage on VIN
2.5
0
V
V
Voltage on LED0 to LED8, C1–, C2–, C1+, C2+, VOUT
Voltage on CLK, ADDR, EN/PWM, GPIO/TRIG/INT, SDA, SCL
Input voltage on V1P8
VVIN
VVIN
1.95
160
85
0
V
1.65
0
V
Output current on VOUT
mA
°C
(1)
Operating ambient temperature, TA
−40
(1) In applications where high power dissipation and/or poor PCB cooling status is present, the maximum ambient temperature might
require derating. Maximum ambient temperature (TA-MAX) is dependent on the maximum operating junction temperature (TJ-MAX-OP
=
125°C), the maximum power dissipation of the device in the application (PD-MAX), and the junction-to ambient thermal resistance of the
device in the application (RθJA), as given by the equation: TA-MAX = TJ-MAX-OP – (RθJA × PD-MAX).
7.4 Thermal Information
LP5569
THERMAL METRIC(1)
RTW (WQFN)
24 PINS
35.8
UNIT
RθJA
Junction-to-ambient thermal resistance
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
RθJC(top)
RθJB
Junction-to-case (top) thermal resistance
Junction-to-board thermal resistance
26.7
13.1
ψJT
Junction-to-top characterization parameter
Junction-to-board characterization parameter
Junction-to-case (bottom) thermal resistance
0.4
ψJB
13.1
RθJC(bot)
4.6
(1) For more information about traditional and new thermal metrics, see Semiconductor and IC Package Thermal Metrics.
Copyright © 2017, Texas Instruments Incorporated
5
LP5569
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
www.ti.com.cn
7.5 Electrical Characteristics
Unless otherwise noted, specifications apply to the LP5569 device in a circuit per the typical application diagram for the single
device with VVIN = 3.6 V, V1P8 = 1.8 V, VEN/PWM = VVIN, CIN = COUT = CFLY1 = CFLY2 = 1 µF. Typical (TYP) values apply for TA =
25°C and minimum (MIN) and maximum (MAX) apply over the operating ambient temperature range (−40°C < TA < 85°C).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNIT
VEN/PWM = 0 V, chip_en (bit) = 0
0.2
1
VEN/PWM = 3.3 V, chip_en (bit) = 0, external CLK
not running
1
2
2
Standby supply current
µA
VEN/PWM = 3.3 V, chip_en (bit) = 0, external CLK
running
4
External CLK running, charge pump and current
sinks disabled
56
65
1.8
10
70
µA
90
IVIN
Charge pump in 1× mode, no load, current
sinks disabled
Normal-mode supply current
Charge pump in 1.5× mode, no load, current-
sink outputs disabled
mA
External CLK running, see Automatic Power-
Save Mode
15
Power-save mode supply
current
µA
Internal oscillator running
10
15
VEN/PWM = 0 V, chip_en(bit) = 0
0.2
1
µA
µA
VEN/PWM = 3.3 V, chip_en (bit) = 0, external CLK
not running
0.2
1
2
Standby supply current
VEN/PWM = 3.3 V, chip_en (bit) = 0, external CLK
running
4
190
190
µA
µA
µA
µA
External CLK running, charge pump and current
sinks disabled
174
174
180
IV1P8
Charge pump in 1× mode, no load, current
sinks disabled
Normal-mode supply current
Charge pump in 1.5× mode, no load, current-
sink- outputs disabled
External CLK running
1
1
5
5
µA
µA
Powersave-mode supply
current
Internal oscillator running
32-kHz internal oscillator
frequency accuracy
TA = 25°C
–10%
–7%
10%
7%
ƒOSC
10-MHz internal oscillator
frequency accuracy
VVIN falling
VVIN rising
2.2
2.3
VUVLO
Undervoltage lockout
V
7.6 Charge-Pump Electrical Characteristics
PARAMETER
TEST CONDITIONS
MIN
TYP
1
MAX
UNIT
Gain = 1×, VVIN = 4.2 V
Gain = 1.5×, VVIN = 3.7 V
ROUT
Charge-pump output resistance
Ω
3.5
VVIN = 3.7 V, IOUT = 160 mA,
gain = 1.5×
VOUT
ƒSW
ICL
4.41
4.5
1.25
600
4.59
V
Switching frequency
Output current limit
MHz
mA
VOUT = 0 V, VVIN = 3.7 V,
CP_CONFIG = 0xFF
IOUT = 0 mA, VIN ≥ 3 V, VOUT
4.1 V, gain = 1.5×
>
tON
VOUT turnon time
100
200
150
µs
VVIN > 3.1 V, VOUT dropped
10%, gain = 1.5×
IOUT
Maximum output current
mA
VIN > 2.5 V, VOUT dropped 10%,
gain = 1.5×
6
Copyright © 2017, Texas Instruments Incorporated
LP5569
www.ti.com.cn
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
7.7 LED Current Sinks Electrical Characteristics
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
1
UNIT
µA
ILEAKAGE
IMAX
Leakage current (LED0 to LED8)
Maximum sink current
PWM = 0%, VLED = 5 V
24.5
25.5
26.5
mA
Current set to 17.5 mA. PWM =
100%
ILED_ACC
Sink current accuracy(1)
–4.5%
4.5%
2.5%
ILED_MATCH Matching(1)
Current set to 17.5 mA
1%
19.5
90
ƒLED
VSAT
LED switching frequency
Saturation voltage(2)
kHz
mV
Output current set to 25.5 mA
110
(1) Output-current accuracy is the difference between the actual value of the output current and the programmed value of this current.
Matching is the maximum difference from the average. For the constant-current outputs on the device (LED0 to LED8), the following are
determined: the maximum output current (MAX), the minimum output current (MIN), and the average output current of all outputs (AVG).
The matching number is calculated: (MAX – MIN) / AVG. The typical specification provided is the most likely norm of the matching figure
for all devices. Note that some manufacturers have different definitions in use.
(2) Saturation voltage is defined as the voltage when the LED current has dropped 10% from the value measured at 1 V.
7.8 Logic Interface Characteristics
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
0.4
1
UNIT
LOGIC INPUT (EN/PWM, SCL, ADDR)
VIL
VIH
Ilkg
Input low level
V
V
Input high level
1.25
–1
Input leakage current
VI ≤ VVIN
µA
LOGIC OUTPUT (SDA, GPIO/TRIG/INT, CLK)
VIL
VIH
Input low level
Input high level
Pin configured as input
Pin configured as input
0.4
V
V
1.25
–1
Pin configured as input, VVIN
= 5.5 V, VI ≤ VVIN
Ilkg
VOL
IL
Input leakage current
Output low level
1
0.5
1
µA
V
IPULLUP = 3 mA
0.2
Pin configured as output, Hi-
Z state
Output leakage current
µA
7.9 Timing Requirements (EN/PWM)
MIN
TYP
MAX
UNIT
tEN
Enable time, EN/PWM first rising edge until first I2C access
2
3
ms
EN timeout, EN/PWM = low time while in standby mode (enable
function)
tEN_TIMEOUT
15
ms
ms
bits
PWM timeout, EN/PWM = low time while in normal mode (PWM
function)
tPWM_TIMEOUT
PWMres
15
10
Resolution for EN/PWM input when configured as PWM, fPWM
=10 kHz
Copyright © 2017, Texas Instruments Incorporated
7
LP5569
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
www.ti.com.cn
7.10 Serial-Bus Timing Requirements (SDA, SCL), See 图 1
I2C fast mode
MIN
MAX
UNIT
kHz
µs
ƒSCL
1
Clock frequency
0
400
Hold time (repeated) START condition
Clock low time
0.6
2
1.3
µs
3
Clock high time
600
ns
4
Setup time for a repeated START condition
Data hold time
600
ns
5
0
100
ns
6
Data setup time
ns
7
Rise time of SDA and SCL
Fall time of SDA and SCL
Setup time for STOP condition
Bus-free time between a STOP and a START condition
Capacitive load for each bus line
20 + 0.1Cb
15 + 0.1Cb
600
300
300
ns
8
ns
9
ns
10
Cb
1.3
µs
10
200
pF
7.11 External Clock Timing Requirements (CLK), See 图 2
over operating ambient temperature range (unless otherwise noted)
MIN
TYP
MAX
UNIT
kHz
µs
ƒCLK
tCLKH
tCLKL
tr
Clock frequency
32.7
High time
6
6
Low time
µs
Clock rise time, 10% rising edge to 90% rising edge
Clock fall time, 90% falling edge to 10% falling edge
2
2
µs
tf
µs
图 1. Timing Parameters
图 2. External Clock Signal
8
版权 © 2017, Texas Instruments Incorporated
LP5569
www.ti.com.cn
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
7.12 Typical Characteristics
Unless otherwise specified: VVIN = 3.6 V, CIN = COUT = 1 μF, C1 = C2 = 1 μF, TA = 25°C. CIN, COUT, C1, C2: Low-ESR surface-
mount ceramic capacitors (MLCCs) used in setting electrical characteristics.
0.9
0.875
0.85
5
4.75
4.5
0.825
0.8
4.25
4
0.775
0.75
3.75
3.5
0.725
0.7
3.25
3
0.675
0.65
VVIN = 3 V
VVIN = 3.3 V
VVIN = 3.6 V
VVIN = 3.9 V
VVIN = 4.2 V
VVIN = 2.5 V
VVIN = 3 V
VVIN = 3.3 V
VVIN = 3.6 V
VVIN = 3.9 V
VVIN = 4.2 V
2.75
2.5
0.625
0
0.02 0.04 0.06 0.08 0.1 0.12 0.14 0.16 0.18 0.2
Load Current (A)
0
10 20 30 40 50 60 70 80 90 100 110 120
Load Current (mA)
D004
D005
图 3. Charge Pump 1.5× Efficiency vs Load Current
图 4. Output Voltage of the Charge Pump (1.5×) as a
Function of Load Current at Six Input Voltage Levels
图 5. Charge Pump (1×) Start-Up Waveform
图 6. Charge Pump (1.5×) Start-Up Waveform
10.2
Internal CLK
External CLK
9.8
9.4
9
8.6
8.2
7.8
7.4
7
2.5
3
3.5
4
4.5
5
5.5
VVIN (V)
D006
图 8. Supply Current in Power-Save Mode vs VVIN
图 7. Charge Pump (Auto) Start-Up Waveform
版权 © 2017, Texas Instruments Incorporated
9
LP5569
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
www.ti.com.cn
Typical Characteristics (接下页)
Unless otherwise specified: VVIN = 3.6 V, CIN = COUT = 1 μF, C1 = C2 = 1 μF, TA = 25°C. CIN, COUT, C1, C2: Low-ESR surface-
mount ceramic capacitors (MLCCs) used in setting electrical characteristics.
1000
900
800
700
600
500
400
300
200
100
0
-1 -0.8 -0.6 -0.4 -0.2
0
0.2 0.4 0.6 0.8
1
D008
Maximum Matching (%)
ILEDx setting per channel = 17.5 mA
图 10. LED Current Matching Distribution
图 9. Serial Bus Write and Charge Pump Start-Up Waveform
4000
3600
3200
2800
2400
2000
1600
1200
800
400
0
-2 -1.6 -1.2 -.8
-.4
0
.4
.8
1.2 1.6
2
D009
Accuracy (%)
ILEDx setting per channel = 17.5 mA
图 11. LED Current Accuracy Distribution
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8 Detailed Description
8.1 Overview
The LP5569 device is a fully integrated lighting management unit for producing lighting effects for various LED
applications. The LP5569 device includes all necessary power management, low-side current sinks, two-wire
serial I2C-compatible interface, and programmable LED engines. The overall maximum current for each of the
nine drivers is set with 8-bit resolution. The LP5569 device controls LED luminance with a pulse-width
modulation (PWM) scheme with a resolution of 12 bits at 20 kHz, which is achieved by using 3-bit dithering.
8.1.1 Programming
The LP5569 device provides flexibility and programmability for dimming and sequencing control. Each LED can
be controlled directly and independently through the serial interface, or LED drivers can be grouped together for
preprogrammed flashing patterns. The device has three independent program execution engines. Each engine
can control 1 to 9 LED driver outputs, but more than one engine cannot simultaneously control the same LED
driver output. Any engine can be used as the master fader for all three engines.
8.1.2 Energy Efficiency
An integrated 1× or 1.5× charge pump with adaptive control provides supply voltage for LEDs when operating
with low input voltage. Because the LED drivers are low-side sinks, some or all LEDs can be powered from an
external source if available. The LP5569 device has very low standby current and an automatic power-save
mode when the LEDs are inactive.
8.1.3 Protection Features
Protection features include power-on reset, charge-pump input-current limiter, thermal shutdown (TSD), and
undervoltage lockout (UVLO).
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8.2 Functional Block Diagram
CFLY1
CFLY2
C1Å
C1+
C2Å
C2+
VIN
VOUT
PGND
CIN
OSC
1X/1.5X Charge Pump
COUT
BIAS
V1P8
VREF
UVLO
LED PWM ENGINE 1
LED PWM ENGINE 2
LED PWM ENGINE 3
SRAM
PROGRAM
MEMORY
256
INSTRUCTIONS
12-bit
PWM
9
Control
VIN
LED0
LED1
LED2
LED3
LED4
LED5
LED6
LED7
LED8
EN/PWM
CTRL
REG
SCL
SDA
8-bit
Current
I2C
9
ADDR
CLK
CONTROL
8-bit
D/A
CLK DET
POR
GPIO/TRIG/INT
THERMAL
SHUTDOWN
AGND
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8.3 Feature Description
8.3.1 Current Sinks
8.3.1.1 Overview
The LP5569 LED drivers are constant-current sources. Maximum output-current scale can be programmed by
control registers up to 25.5 mA. The overall maximum current is set by 8-bit output current-control registers with
100-μA step size. Each of the 9 LED drivers has a separate output-current control register. The LED luminance
pattern (dimming) is controlled with a PWM technique, which has 12-bit resolution during ramping and 8-bit user
control. The LED current-sink PWM frequency is 20 kHz.
High 20-kHz PWM frequency and 12-bit control accuracy are achieved by using 3-bit dithering for PWM control.
There is a 9-bit pure PWM resolution generated in the PWM generators, and one least-significant bit (1 LSB) is
toggled in eight periods to output a smaller average step. For 3-bit dithering, every eighth pulse is made 1 LSB
longer to increase the average value by 1 / 8th. 图 12 shows an example of 9-bit PWM value, step of 4 / 8 (0.5)
and its 12-bit representation.
256 (9-bit)
2048 (12-bit)
1LSB
256 4/8 (9-bit)
2052 (12-bit)
257 (9-bit)
2056 (12-bit)
图 12. Dithering
A phase-shift PWM scheme allows delaying the time when each LED driver is active. When the LED drivers are
not activated simultaneously, the peak load current from the charge-pump output is greatly decreased. This also
reduces input-current ripple and ceramic-capacitor audible ringing. LED drivers are grouped into three different
phases. In phase 1, the rising edge of the PWM pulse is fixed in time. In phase 2, the middle point of the PWM
pulse is fixed, and the pulse spreads to both directions when PWM duty cycle is increased. Phase 3 has a fixed
falling edge, that is, the rising edge of the pulse is changed when the duty cycle changes.
Cycle Time
1/fPWM
LED0
Phase 1 LED3
LED6
0 mA
LED1
LED4
LED7
Phase 2
Phase 3
0 mA
0 mA
LED2
LED5
LED8
Phase 1
Phase 2
Phase 3
Copyright © 2016, Texas Instruments Incorporated
图 13. LED Phase Shift
LED dimming is controlled according to an exponential or linear scale (see 图 14) In exponential mode, the PWM
output percent can be approximated by the following two equations:
•
•
.
Less than or equal to code 64: y = 0.0125x – 0.0066.
Greater than code 64: y = 0.7835e0.0217x
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Feature Description (接下页)
100,0
100
80
60
40
20
0
0
64
128
192
256
DIMMING CONTROL (DEC)
图 14. 8-Bit User PWM Control, Exponential and Linear Dimming
8.3.1.2 Controlling the Low-Side Current Sinks
8.3.1.2.1 Direct Register Control
All LP5569 LED drivers, LED0 to LED8, can be controlled independently through the two-wire serial I2C-
compatible interface. For each low-side driver there is an 8-bit PWM control register which can be used to control
the LED PWM duty-cycle value. This register cannot be written when the program execution engine is active,
which could result in undesirable behavior. Care should be taken to update these registers only when the
program execution engine is idle.
8.3.1.2.2 Controlling by Program Execution Engines
Engine control is used when the user wants to create programmed sequences. The program execution engine
updates the direct-control registers when active. Therefore, if the user has set the PWM register to a certain
value, it is automatically overridden when the program execution engine controls the driver. LED control and
program-execution-engine operation is described in Programming.
8.3.1.2.3 Master Fader Control
In addition to LED-by-LED PWM register control, the LP5569 device is equipped with a master-fader control,
which allows the user to fade in or fade out multiple LEDs from the EN/PWM pin or by writing to the master fader
registers. This is a useful function to minimize serial bus traffic between the MCU and the LP5569 device. The
LP5569 device has three master fader registers, so it is possible to form three master fader groups. Either writing
master fader registers through the I2C interface directly or through LED engine control can set the master fader
register values. The final output PWM duty cycle is the PWM register duty-cycle value multiplied by the duty-
cycle value of the master fader register.
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Feature Description (接下页)
图 15. Simplified Data Flow of Master Fader
8.3.1.2.3.1 PWM Master Fader on EN/PWM Pin
The EN/PWM pin provides a dual-function input. On power up, the pin functions as the device enable (EN)
function, where the first rising edge enables the LP5569 device. After the chip_en bit is set high in the CONFIG
register, the pin is reconfigured for PWM master-fader control of the LEDs. The LEDx_CONTROL register
(addresses 07h–0Fh) MF_MAPPINGx bits = 5h configures LEDx for PWM control.
The PWM input is a sampled input which converts the input duty-cycle information into an 11-bit code. The use
of a sampled input eliminates any noise and current ripple that is typical of traditional PWM-controlled LED
drivers. The PWM input uses logic-level thresholds with VIH_MIN = 1.25 V and VIL_MAX = 0.4 V. Because this is a
sampled input, there are limits on the maximum PWM input frequency as well as the resolution that can be
achieved.
8.3.1.2.3.2 PWM Master Fader Resolution and Input Frequency Range
The PWM input frequency range is 100 Hz to 20 kHz. To achieve the full 11-bit maximum resolution of PWM
duty cycle to the code, the input PWM duty cycle must be ≥ 11 bits, and the PWM sample period (1 / fSAMPLE
)
must be smaller than the minimum PWM input pulse duration. 图 16 shows the possible brightness code
resolutions based on the input PWM frequency.
Sample Frequency = 10MHz
12
11
10
9
8
7
6
0.1
0.2 0.3 0.5 0.7
1
2
3
4
5 6 78 10
20
PWM Frequency
D003
图 16. PWM Resolution vs PWM Input Frequency
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Feature Description (接下页)
8.3.1.2.3.3 PWM Master Fader Hysteresis
To prevent jitter on the input PWM signal from feeding through the PWM path and causing oscillations in the LED
current, the LP5569 device offers seven selectable hysteresis settings. The hysteresis works by forcing a specific
number of 11-bit LSB code transitions to occur in the input duty cycle before the LED current changes. 表 1
describes the hysteresis. The hysteresis only applies during a change in direction of brightness currents. Once
the change in direction has taken place, the PWM input must overcome the required LSB(s) of the hysteresis
setting before the brightness change takes effect. Once the initial hysteresis has been overcome and the
direction in brightness change remains the same, the PWM-to-current response changes with no hysteresis.
表 1. PWM Input Hysteresis
MIN. CHANGE
IN PWM DUTY
CYCLE (ΔD)
MIN (ΔILED), INCREASE FOR INITIAL CODE
MIN. CHANGE IN PWM PULSE
HYSTERESIS
SETTING
(0x80 bits
[2:0])
DURATION (Δt) REQUIRED TO REQUIRED TO
CHANGE LED CURRENT,
AFTER DIRECTION CHANGE
(for fPWM < 11.7 kHz)
CHANGE LED
CURRENT
AFTER
EXPONENTIAL MODE
LINEAR MODE
DIRECTION
CHANGE
000 (0 LSB)
001 (1 LSB)
010 (2 LSB)
011 (3 LSB)
100 (4 LSB)
101 (5 LSB)
110 (6 LSB)
1 / (fPWM × 2047)
1 / (f PWM× 1023)
1 / (fPWM × 511)
1 / (fPWM × 255)
1 / (fPWM × 127)
1 / (fPWM × 63)
1 / (fPWM × 31)
0.05%
0.1%
0.3%
0.61%
1.21%
2.4%
0.05%
0.1%
0.2%
0.2%
0.39%
0.78%
1.56%
3.12%
0.39%
0.78%
1.56%
3.12%
4.74%
9.26%
17.66%
tJITTER
tJITTER
D/fPWM
1/fPWM
ñ
ñ
ñ
D is tJITTER x fPWM or equal to #LSB‘s = ∆D x 2048 codes.
For 11-bit resolution, #LSBs is equal to a hysteresis setting of LN(#LSB‘s)/LN(2).
For example, with a tJITTER of 1 µs and a fPWM of 5 kHz, the hysteresis setting should be:
LN(1 µ s x 5 kHz x 2048)/LN(2) = 3.35 (4 LSBs).
Copyright © 2016, Texas Instruments Incorporated
图 17. PWM Hysteresis Example
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8.3.1.2.4 EN/PWM Input Timeout
The EN/PWM input timeout feature has two operating modes as follows:
•
STANDBY state: EN/PWM low for > 15 ms shuts down the LP5569 device and returns to the DISABLED
state (see 图 20).
8.3.2 Charge Pump
8.3.2.1 Overview
The LP5569 device includes a pre-regulated switched-capacitor charge pump with a programmable voltage
multiplication of 1× or 1.5×. In 1.5× mode, by combining the principles of a switched-capacitor charge pump and
a linear regulator, a regulated 4.5-V output is generated from the VIN input within its normal voltage range. A
two-phase non-overlapping clock, generated internally, controls the operation of the charge pump. During the
charge phase, both flying capacitors (CFLY1 and CFLY2) are charged from input voltage. In the pump phase that
follows, the flying capacitors are discharged to the output. A traditional switched-capacitor charge pump
operating in this manner uses switches with very low on-resistance, ideally 0 Ω, to generate an output voltage
that is 1.5× the input voltage. The LP5569 device regulates the output voltage by controlling the resistance of the
input-connected pass-transistor switches in the charge pump.
8.3.2.2 Pre-Regulation
The very low input-current ripple of the LP5569 device, resulting from internal pre-regulation, adds minimal noise
to the input line. The core of the LP5569 device is very similar to that of a basic switched-capacitor charge pump:
it is composed of switches and two flying capacitors (external). Regulation is achieved by controlling the current
through the switches connected to the VIN pin (one switch in each phase). The regulation occurs before the
voltage multiplication, giving rise to the term pre-regulation. It is pre-regulation that eliminates most of the input-
current ripple that is a typical and undesirable characteristic of a many switched-capacitor converters.
8.3.2.3 Input Current Limit
The LP5569 device contains current-limit circuitry that protects the device in the event of excessive input current
and/or output shorts to ground. The input current is limited to 600 mA (typical) when the output is shorted directly
to ground. When the LP5569 device is current limiting, power dissipation in the device is likely to be quite high. In
this event, thermal cycling should be expected.
8.3.2.4 Output Discharge
The LP5569 device provides a feature to discharge the charge-pump output capacitor. The charge-pump output
pulldown is not enabled when the MISC2 register (address 33h) CP_DIS_DISCH bit = 1. The charge pump
output pulldown is enabled when the CP_DIS_DISCH bit = 0. The pulldown draws a minimal current from the
output capacitor (300 μA typical) when in the SHUTDOWN and STANDBY states.
8.3.2.5 Controlling the Charge Pump
The charge pump is controlled with two CP_MODE bits in the MISC register (address 2Fh). When both of the
bits are low, the charge pump is disabled, and output voltage is pulled down as described in Output Discharge.
The charge pump can be forced to the bypass mode, so the battery voltage is connected directly to the current
source; in 1.5× mode the output voltage is boosted to 4.5 V. In automatic mode, the charge-pump operation
mode is determined by saturation of the constant-current drivers described in LED Forward Voltage Monitoring.
8.3.2.6 LED Forward Voltage Monitoring
When the charge-pump automatic-mode selection is enabled, voltages on the LED current sinks LED0 to LED8
are monitored. If the current sinks do not have enough headroom, the charge pump gain is set to 1.5× and
remains in 1.5× mode until one of the following occurs:
•
•
•
The LP5569 device enters the SHUTDOWN state and goes through the INITIALIZATION or STARTUP state.
The charge-pump mode is forced to 1× mode via the MISC register.
The LP5569 device exits power save when the charge pump is in automatic mode (CP_MODE bits = 3h).
A current-sink saturation monitor is selectable to one of four fixed voltage thresholds. The charge-pump gain is
set to 1× when the battery voltage is high enough to supply all LEDs. Note: forward-voltage monitoring is
disabled when the LEDx_CONTROL (addresses 07h–0Fh) register EXTERNAL_POWERx bit = 1.
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MODE
VOUT
LEDx
VIN
CHARGE PUMP
CURRENT SINK
PWM
V
OFS
COMPARATOR
SATURATION
MONITOR
CONTROL
REGISTERS
MODE
CONTROL
Copyright © 2016, Texas Instruments Incorporated
图 18. Forward-Voltage-Monitoring and Gain-Control Block
8.3.3 Energy Efficiency
8.3.3.1 LED Powering
The red LED (R) element of an RGB LED typically has a forward voltage of about 2 V. These LEDs can be
powered directly from the input voltage because battery voltage is typically high enough to drive red LEDs over
the whole operating voltage range. This allows driving of three RGB LEDs with good efficiency because the red
LEDs do not load the charge pump. When the LEDx_CONTROL (address 07h–0Fh) register
EXTERNAL_POWERx bit = 1, the LEDx output is configured for external supply, and forward-voltage monitoring
is disabled.
8.3.4 Automatic Power-Save Mode
When the LED outputs are not active, the LP5569 device is able to enter the power-save mode automatically,
thus lowering idle-current consumption down to 10 μA (typical). Automatic power-save mode is enabled when the
MISC register (address 2Fh) POWERSAVE_EN bit = 1. Almost all analog blocks are powered down in power
save, if an external clock signal is used. The charge pump enters the weak 1× mode using a passive current-
limited keep-alive switch, which keeps the output voltage at the battery level to reduce output-voltage transients.
During program execution, the LP5569 device can enter power save if there is no PWM activity in any of the LED
driver outputs. To prevent short power-save sequences during program execution, the device has an instruction
look-ahead filter. In power-save mode, program execution continues without interruption. When an instruction
that requires PWM activity is executed, a fast internal start-up sequence is started automatically.
8.3.5 Protection Features
8.3.5.1 Thermal Shutdown (TSD)
The LP5569 device implements a thermal shutdown mechanism to protect the device from damage due to
overheating. When the junction temperature rises to 150°C (typical), the device switches into shutdown mode.
The LP5569 device releases thermal shutdown when the junction temperature of the device decreases to 130°C
(typical).
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Thermal shutdown is most often triggered by self-heating, which occurs when there is excessive power
dissipation in the device and/or insufficient thermal dissipation. LP5569 power dissipation increases with
increased output current and input voltage. When self-heating brings on thermal shutdown, thermal cycling is the
typical result. Thermal cycling is the repeating process where the part self-heats, enters thermal shutdown
(where internal power dissipation is practically zero), cools, turns on, and then heats up again to the thermal
shutdown threshold. Thermal cycling is recognized by a pulsing output voltage and can be stopped by reducing
the internal power dissipation (reduce input voltage and/or output current) or the ambient temperature. If thermal
cycling occurs under desired operating conditions, thermal dissipation performance must be improved to
accommodate the power dissipation of the LP5569 device. The QFN package is designed to have excellent
thermal properties that, when soldered to a PCB designed to aid thermal dissipation, allows the LP5569 device to
operate under very demanding power-dissipation conditions.
8.3.5.2 Undervoltage Lockout (UVLO)
The LP5569 device has an internal comparator that monitors the voltage at VIN. If the input voltage drops to
2.2 V (nominal), undervoltage is detected, the LED outputs and the charge pump shut down, and the
corresponding fault bit is set in the fault register. Hysteresis is implemented for the threshold level to avoid
continuous triggering of a fault when the threshold is reached. If the input voltage rises above 2.3 V (nominal),
the LP5569 device resumes normal operation.
8.3.5.3 Power-On Reset (POR)
The LP5569 device has internal comparators that monitor the voltages at VIN and V1P8. When VVIN is below 2.2
V or V1P8 is below 1.3 V, reset is active and the LP5569 device is in the DISABLED state.
8.3.5.4 LED Fault Detection
The LP5569 device contains both open-LED and shorted-LED fault detection. These fault detections are
designed to be used in production-level testing and not normal operation. For the fault flags to operate, they must
be enabled via the MISC2 register (address 33h) LED_OPEN_TEST and LED_SHORT_TEST bits. The fault
flags are shared by both open-LED and shorted-LED tests so only one can be enabled at a time. The default
LED-fault status is ready in the LED_FAULT1 and LED_FAULT2 registers (addresses 81h and 82h). The
following sections detail the proper procedure for reading back open and short faults in the LED strings.
8.3.5.4.1 Open LED
The LP5569 device features one fault flag per LED, indicating one or more of the active low-voltage LED strings
are open. An open in a low-voltage LED string is flagged if the voltage at the input to any active low-voltage
current sink goes below the drv_headroom[1:0] setting in the MISC2 register. The procedure for detecting an
open-LED fault is:
1. Set the LP5569 device in the STANDBY state.
2. Configure the charge pump in the 1.5× mode.
3. Set the LED_OPEN_TEST bit = 1 in the MISC2 register (address 33h).
4. Set the chip_en bit = 1 in the CONTROL register (address 0h) with the LP5569 device in the NORMAL state.
5. Wait at least 500 µs.
6. Enable all LEDs, and set all LEDs to 100% brightness.
7. Wait at least 500 µs.
8. Check the fault status of the LED_FAULT1 and LED_FAULT2 registers.
9. Set the LED_OPEN_TEST bit = 0 in the MISC2 register (address 33h).
10. Set all LEDs to 0% brightness.
8.3.5.4.2 Shorted LED
The LP5569 device features one fault flag per LED, indicating when any active LED is shorted (anode to
cathode). During the LED short test, the charge pump is forced to the 1× mode. A short in the LED is determined
when the LED voltage (VIN –V LEDx) falls below 1 V. The procedure for detecting a shorted-LED fault is:
1. Set the LP5569 device in the STANDBY state.
2. Configure the charge pump in the 1× mode, set LED PWM (0x16–0x1E) and LED current (0x22–0x2A) to
maximum value, depending on the LED channel being tested.
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3. Set the chip_en bit in the CONFIG register = 1 and the LP5569 device to the NORMAL state.
4. Wait at least 500 µs.
5. Enable all LEDs, and set brightness to 100%.
6. Set the LED_SHORT_TEST bit = 1 in the MISC2 register (address 33h).
7. Wait at least 500 µs.
8. Check the fault status of the LED Fault1 and LED Fault2 registers.
9. Set the LED_SHORT_TEST bit = 0 in in the MISC2 register (address 33h).
10. Set all LEDs to 0% brightness.
8.3.6 Clock Generation and Synchronization
The LP5569 device can generate a 32-kHz clock signal and use it for synchronizing multiple devices. The CLK
pin is configured as an input by default. When the EN_CLK_OUT bit = 1 in the IO_CONTROL register (address
3Dh) the LP5569 device drives the CLK pin using its 32-kHz oscillator.
Set up as
Clock master
VIN 1.8V
VIN
VIN 1.8V
VIN 1.8V
1.8V
V1P8
V1P8
VIN
V1P8
VIN
V1P8
VIN
VIN
ADDR
ADDR
ADDR
ADDR
SCL
SDA
SCL
SDA
SCL
SDA
SCL
SDA
SCL
SDA
SCL
SDA
SCL
SDA
SCL
SDA
CLK
CLK
CLK
CLK
GPIO/TRIG/INT
GPIO/TRIG/INT
GPIO/TRIG/INT
GPIO/TRIG/INT
VIN
Copyright © 2016, Texas Instruments Incorporated
图 19. Synchronizing Multiple Devices Using the Clock Generator
8.3.7 GPIO/TRIG/INT Multifunctional I/O
The GPIO/TRIG/INT pin is configured by the GPIO_CONFIG bits in the IO_CONTROL register (address 3Dh).
The default configuration for this pin is the INT function.
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8.4 Device Functional Modes
8.4.1 Modes Of Operation
CP_LED_STARTUP: LED drivers are enabled. The device enters NORMAL after 300 µs (typical).
CP_ON:
Charge pump is enabled per CP_MODE bits, and charge-pump output voltage is within regulation
after 300 µs (typical).
CP_WAKEUP After the power-save condition is no longer met, the device enters the CP_WAKEUP state. The
device enters CP_LED_STARTUP after 100 µs (typical).
DISABLED: The device enters this state when logic receives POR or the EN/PWM pin is low for longer than 15
ms (typical). The internal logic is disabled in this state to minimize power consumption. The mode
changes to INITIALIZATION when a rising edge has been detected in the EN/PWM pin and TSD is
inactive.
INITIALIZATION: This state duration is 2 ms (typical). The device enters the OTP_READ–SRAM_INIT state if
VVIN is above the VUVLO level, and the temperature is below TSD. If VVIN is below VUVLO or TSD is
active, the device remains in INITIALIZATION unless EN/PWM is low for 15 ms (typical), then the
device enters the DISABLED mode.
INTERNAL POWER SHUTDOWN:In INTERNAL POWER SHUTDOWN mode, the internal LDO is shutdown.
NORMAL: After startup has been completed the device enters the NORMAL mode. Users can drive LEDs and
execute programs in this mode.
OTP_READ - SRAM_INIT: The OTP_READ mode is followed by SRAM_INIT, which initializes SRAM. When
initialization is complete, the device enters the STANDBY state. If VIN is below VUVLO while in this
state, the device returns to INITIALIZATION.
POWER SAVE:In POWER SAVE mode, analog blocks are disabled to minimize power consumption. After the
power-save condition is no longer met, the device exits the POWER SAVE mode. See Automatic
Power-Save Mode section for further information.
SHUTDOWN: During shutdown, the charge-pump and LED drivers are disabled. The device enters the
shutdown state if disabled (chip_en = 0) or if a TSD fault is active. The device enters STANDBY
after 1 ms (typical).
STANDBY: The STANDBY mode is a low-power-consumption mode and is entered if the register bit chip_en is
zero and Reset is not active. Register and SRAM access is available via I2C.
START-UP: During a fault condition, device operation is halted, and the device waits in STARTUP mode until no
faults are present. UVLO detection returns the device to STARTUP from all states with the
exception of STANDBY, INITIALIZATION, and OTP_READ - SRAM_INIT.
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Device Functional Modes (接下页)
图 20. LP5569 Function State Machine
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8.5 Programming
8.5.1 I2C Interface
The I2C-compatible two-wire serial interface provides access to the programmable functions and registers on the
device. This protocol uses a two-wire interface for bidirectional communications between the devices connected
to the bus. The two interface lines are the serial data line (SDA) and the serial clock line (SCL). Every device on
the bus is assigned a unique address and acts as either a master or a slave depending on whether it generates
or receives the serial clock, SCL. The SCL and SDA lines should each have a pullup resistor placed somewhere
on the line and remain HIGH even when the bus is idle. Note: the CLK pin is not used for serial bus data
transfer.
8.5.1.1 Data Validity
The data on SDA line must be stable during the HIGH period of the clock signal (SCL). In other words, state of
the data line can only be changed when clock signal is LOW.
SCL
SDA
data
change
allowed
data
change
allowed
data
valid
data
change
allowed
data
valid
图 21. Data Validity Diagram
8.5.1.2 Start and Stop Conditions
START and STOP conditions classify the beginning and the end of the data transfer session. A START condition
is defined as the SDA signal transitioning from HIGH to LOW while SCL line is HIGH. A STOP condition is
defined as the SDA transitioning from LOW to HIGH while SCL is HIGH. The bus master always generates
START and STOP conditions. The bus is considered to be busy after a START condition and free after a STOP
condition. During data transmission, the bus master can generate repeated START conditions. First START and
repeated START conditions are functionally equivalent.
8.5.1.3 Transferring Data
Every byte put on the SDA line must be eight bits long, with the most significant bit (MSB) being transferred first.
Each byte of data must be followed by an acknowledge bit. The acknowledge-related clock pulse is generated by
the master. The master releases the SDA line (HIGH) during the acknowledge clock pulse. The LP5569 device
pulls down the SDA line during the ninth clock pulse, signifying an acknowledge. The LP5569 device generates
an acknowledge after each byte has been received.
There is one exception to the acknowledge after every byte rule. When the master is the receiver, it must
indicate to the transmitter an end of data by not-acknowledging (negative acknowledge) the last byte clocked out
of the slave. This negative acknowledge still includes the acknowledge clock pulse (generated by the master),
but the SDA line is not pulled down.
After the START condition, the bus master sends a device address. This address is seven bits long followed by
an eighth bit which is a data direction bit (READ or WRITE). For the eighth bit, a 0 indicates a WRITE, and a 1
indicates a READ. The second byte selects the register to which the data is to be written. The third byte contains
data to write to the selected register.
8.5.1.4 I2C Slave Addressing
The LP5569 slave address is defined by connecting GND, SCL, SDA, or VIN to the ADDR pin. A total of four
slave addresses can be realized by combinations when GND, SCL, SDA, or VIN is connected to the ADDR pin
(see 表 2).
The LP5569 device is available in two versions (LP5569 and LP5569A). Each version has four possible address
settings, which allows up to eight devices sharing the same I2C bus as shown in 表 2. Values are in 7-bit slave ID
format. The LP5569 device responds to slave address 40h regardless of the setting of the ADDR pin and device
version. Global writes to address 40h can be used for configuring all devices simultaneously. The LP5569 device
supports global read using slave address 40h; however, the data read is only valid if all LP5569 devices on the
I2C bus contain the same value in the register read.
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表 2. LP5569 Slave-Address Combinations
SLAVE ID
32h and 40h
33h and 40h
34h and 40h
35h and 40h
42h and 40h
43h and 40h
44h and 40h
45h and 40h
VERSION
ADDR
GND
SCL
SDA
VIN
A
A
A
A
GND
SCL
SDA
VIN
MSB
LSB
ADR6
bit7
ADR5
bit6
ADR4
bit5
ADR3
bit4
ADR2
bit3
ADR1
bit2
ADR0
bit1
R/W
bit0
2
I C Slave Address (chip address)
图 22. LP5569 Chip Address
8.5.1.5 Control Register Write Cycle
1. The master device generates a start condition.
2. The master device sends the slave address (7 bits) and the data direction bit (R/W = 0).
3. The slave device sends an acknowledge signal if the slave address is correct.
4. The master device sends the control register address (8 bits).
5. The slave device sends an acknowledge signal.
6. The master device sends the data byte to be written to the addressed register.
7. The slave device sends an acknowledge signal.
8. If the master device sends further data bytes, the control register address of the slave is incremented by 1
after the acknowledge signal. In order to reduce program load time, the LP5569 device supports address
auto incrementation. The register address is incremented after each 8 data bits. For example, the whole
program memory page can be written in one serial-bus write sequence.
9. The write cycle ends when the master device creates a stop condition.
ack from slave
ack from slave
ack from slave
start
MSB Chip Addr LSB
w
ack MSB Register Addr LSB ack
MSB Data LSB
ack
stop
SCL
SDA
start
id = 32h
w
ack
addr = 40h
ack
address 40h data
ack stop
图 23. Write Cycle (W = Write; SDA = 0)
8.5.1.6 Control Register Read Cycle
1. The master device generates a start condition.
2. The master device sends the slave address (7 bits) and the data direction bit (R/W = 0).
3. The slave device sends an acknowledge signal if the slave address is correct.
4. The master device sends the control register address (8 bits).
5. The slave device sends an acknowledge signal.
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6. The master device generates a repeated-start condition.
7. The master device sends the slave address (7 bits) and the data direction bit (R/W = 1).
8. The slave device sends an acknowledge signal if the slave address is correct.
9. The slave device sends the data byte from the addressed register.
10. If the master device sends an acknowledge signal, the control register address is incremented by 1. The
slave device sends the data byte from the addressed register.
11. The read cycle ends when the master device does not generate an acknowledge signal after a data byte
and generates a stop condition.
ack from slave
ack from slave repeated start
ack from slave data from slave nack from master
start
MSB Chip Addr LSB
w
MSB Register Addr LSB
rs
MSB Chip Address LSB
r
MSB Data LSB
stop
SCL
SDA
start
id =32h
w
ack
address = 3Fh
ack rs
id = 32h
r
ack
address 3Fh data
nack stop
ID = chip address = 32h for the LP5569 device
图 24. Read Cycle (R = Read; SDA = 1)
8.5.1.7 Auto-Increment Feature
The auto-increment feature allows writing several consecutive registers within one transmission. Every time an
8‑bit word is sent to the LP5569 device, the internal address index counter is incremented by 1, and the next
register is written. The auto-increment feature is enabled by default and can be disabled by setting the
EN_AUTO_INCR bit = 0 in the MISC register (address 2Fh).
8.5.2 Execution Engine Programming
The LP5569 device provides flexibility and programmability for dimming and sequencing control. Each LED can
be controlled directly and independently through the serial bus, or LED drivers can be grouped together for pre-
programmed flashing patterns.
The LP5569 device has three independent program execution engines, so it is possible to form three
independently programmable LED banks. LED drivers can be grouped based on their function so that, for
example, the first bank of drivers can be assigned to the keypad illumination, the second bank to the funlights,
and the third group to the indicator LED(s). Each bank can contain 1 to 9 LED driver outputs. Instructions for
program execution engines are stored in the program memory. The total amount of the program memory is 255
instructions, and the user can allocate the instructions as required by the engines; however, a single engine can
only allocate up to ½ the memory (128 instructions).
8.5.2.1 SRAM Memory
The LP5569 device has internal SRAM for the three LED engines. SRAM can contain up to 255 16-bit
instructions (addresses 0 through 254) with a maximum size of 128 16-bit instructions for a single engine. SRAM
memory address 255 is reserved and must not be allocated to any LED engine. Memory allocation among the
three LED engines is done dynamically, so that each LED engine has a separate start address and program
counter (PC) that are set in the ENGINEx_PROG_START registers (addresses 4Bh, 4Ch, 4Dh) and
ENGINEx_PC registers (addresses 30h, 31h, 32h). This allows flexible memory allocation among the LED
engines, and multiple engines can recall the same memory address. The program counter uses relative memory
addressing; when the PC is zero the engine is executing an instruction at its start address.
The SRAM is loaded via the I2C interface in 33-byte-length pages. The first byte contains the program-memory-
page-select (address 4Fh) followed by up to 32 bytes containing compiled program execution engine instructions
(address 50h thru 6Fh). Engines must be set to load the program mode (register 01h) before writing the SRAM.
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8.5.2.2 Variables
The LP5569 device has four LED engine variables which are divided into local and global variables. Variables A
and B are engine-specific local variables and each of the three engines has separate A and B variables, so there
is a total of six A and B variables. Variable A can be read and written via I2C registers 42h–44h. Local variable B
is not available via I2C and can only be accessed by the LED engine. Variables C and D are global variables
which are shared by all three LED engines. Global variable C is not available via I2C and can only be accessed
by the LED engines. The D variable can be read and written via I2C register 3Eh. Variables are referenced to
instructions with 2 bits, see 表 3 for details. Note that some instructions (ld, add, sub) can use only variables A,
B, and C as target variables.
表 3. LED Engine Variables
VARIABLE
BITS
00
LOCAL/GLOBAL
Local
A
B
C
D
01
Local
10
Global
11
Global
8.5.2.3 Instruction Set
The LP5569 device has three independent programmable execution engines. All the program execution engines
have their own program memory block allocated by the user. The maximum program size for any one engine is
limited to 128 locations. At least one engine must be in the load-program mode with the engine-busy bit cleared
before writing to any program memory address. Program execution is clocked with a 32.768-kHz clock.
Instruction execution takes sixteen clock cycles (488 μs). This applies also to ramp and wait instructions where
execution time is a multiple of 488 μs. This clock can be generated internally or an external clock can be supplied
to the CLK pin. Using an external clock enables synchronization of LED timing to the external clock signal and is
also more power-efficient. The supported instruction set is listed in 表 4 through 表 6. The LP5569 device is fully
compatible with the LP5523 instruction set. A command compiler is available for easy sequence programming.
With the command compiler it is possible to write sequences with simple ASCII commands, which are then
converted to binary or hex format.
表 4. LED Driver Instructions
INSTRUCTION
ramp(1)
USAGE
COMPILER EXAMPLE
Generate a programmable PWM ramp to mapped LED driver(s) from
the current value to a new value in steps of +1 or –1 with programmed
step time.
ramp 0.6, 255; ramp to full scale in 0.6 s
ramp(2)
ramp var1, prescale, var2 var1 is a variable (ra, rb, rc, rd); prescale is a ld ra, 31 ld rb, 255 ramp ra, pre=0, +rb; ramp
boolean constant (pre = 0 or pre = 1); Var2 is a variable (ra, rb, rc, rd). up to full scale over 3.9 s.
Output PWM with increasing or decreasing duty cycle.
set_pwm(1)
set_pwm(2)
wait
Set PWM or current value to mapped LED driver(s), effective
immediately.
set_pwm 128; set duty cycle to 50%.
set_pwm var1 Var1 is a variable (ra, rb, rc, rd). Generate a continuous ld rc, 128; set_pwm rc; set PWM duty cycle
PWM output.
to 50%.
Wait for a given time. Time span is from 0.488 ms to 484 ms.
wait 0.4; wait for 0.4 s; wait for 0.4 s
(1) This opcode is used with numerical operands.
(2) This opcode is used with variables.
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表 5. LED Mapping Instructions
INSTRUCTION(1)
load_start
ACT(2)
USAGE
COMPILER EXAMPLE
Define the LED mapping-table start address in SRAM.
load_start 01h; starting address
at 01h
map_start
load_end
map_sel
x
Define the LED mapping-table start address in SRAM and set that
address active.
map_start 01h; starting address
at 01h
Define the last address of the LED mapping table in SRAM.
load_end 03h; last address at
03h
x
Connect one LED driver to the LED engine.
map_sel 0; select LED0 as
output
map_clr
x
x
Clear the LED driver mappings in an engine
map_clr
map_next
Select the next address in the LED mapping table and set that address map_next
active.
map_prev
x
Select the previous address in the LED mapping table and set that
address active.
map_prev
load_next
load_prev
load_addr
Move the mapping-table pointer to the next address.
Move the mapping-table pointer to the previous address.
Set the mapping-table pointer to the assigned address.
load_next
load_prev
load_addr 02h; set pointer to
02h
map_addr
x
Set the mapping-table pointer to the assigned address and set that
address active.
map_addr 02h; set mapping to
02h
(1) These instructions are compatible with the LP5523 and LP55231 mux_* LED mapping instructions.
(2) x - The instruction activates LED mapping to the driver when the instruction is executed.
表 6. Branch Instructions
INSTRUCTION
USAGE
Reset program counter to zero.
COMPILER EXAMPLE
rst
Reset
branch 20, loop1; do 20 loops to loop1 label
branch(1)
branch(2)
int
Branch to address. The number of loops can be set to a value or
do an infinite loop.
Branch to address. The loop count can be one of four variables A, ld ra, 20 branch ra, loop1; do 20 loops to
B, C, or D. loop1 label
Send an interrupt to the host system by pulling the GPIO/TRIG/INT int
pin low.
end
End program execution and reset the program counter to zero.
Can also the set GPIO/TRIG/INT pin high and/or reset mapped
LED PWM and engine LED mapping.
end; end and reset LEDs.
trigger
Wait or send trigger. The trigger can be sent or received from an
external pin or another engine.
trigger w{e}; wait for external trigger
trig_clear(3)
Clear pending triggers.
Jump if not equal. A != B
Jump if less. A < B
trig_clear
jne
jl
Jump to loop1 if A != B: jne ra, rb, loop1
Jump to loop1 if A < B : jl ra, rb, loop1
Jump to loop1 if A >= B: jge ra, rb, loop1
Jump to loop1 if A = B: je ra, rb, loop1
jge
je
Jump if greater or equal. A ≥ B
Jump if equal. A = B
(1) This opcode is used with numerical operands.
(2) This opcode is used with variables.
(3) This is a new instruction, not available in LP5523 or LP55231
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表 7. Data Transfer and Arithmetic
INSTRUCTION
USAGE
COMPILER EXAMPLE
ld(1)
add(1)
add(2)
Assign a value to a variable.
Add the 8-bit value to the variable value.
ld ra, 33; load value 33h to local variable A
add ra, 11; add value 11h to local variable A
Add the value of variable 3 (global variable D) to the value of variable 2 add ra, rc, rd; add the value in rd to rc and
(global variable C) and store the result in variable 1 (local variable A).
store in ra
sub(1)
sub(2)
Subtract the 8-bit value from the variable value.
sub ra, 11; subtract value 11h from local
variable A
Subtract the value of variable 3 (global variable D) from the value of
variable 2 (global variable C) and store the result in variable 1 (local
variable A).
sub ra, rc, rd; subtract the value in rd from rc
and store in ra
(1) This opcode is used with numerical operands.
(2) This opcode is used with variables.
8.5.2.4 LED Driver Instructions
表 8. LP5569 LED Driver Instructions
Bit
[15]
Bit
[14]
Bit
[13]
Bit
[12]
Bit
[11]
Bit
[10]
Bit
[9]
Bit
[8]
Bit
[7]
Bit
[6]
Bit
[5]
Bit
[4]
Bit
[3]
Bit
[2]
Bit
[1]
Bit
[0]
INST.
ramp(1)
pre-
scale
0
1
step time
0
sign
0
no. of increments
pre-
scale
no. of
increments
ramp(2)
0
0
0
1
0
0
0
sign
step time
set_pwm(1)
set_pwm(2)
0
1
1
0
0
0
0
0
0
0
0
1
0
0
0
0
PWM value
0
0
1
0
1
0
0
0
0
0
PWM value
pre-
scale
wait
0
time
0
0
0
0
0
(1) This opcode is used with numerical operands.
(2) This opcode is used with variables.
8.5.2.4.1 Ramp
This is the instruction useful for smoothly changing from one PWM value into another PWM value on the LED0 to
LED8 outputs —in other words, generating ramps with a negative or positive slope. The LP5569 device allows
the programming of very fast and very slow ramps using only a single instruction. Full ramp 0 to 255 ramp time
ranges from 124 ms to 4 s.
The ramp instruction generates a PWM ramp, using the effective PWM value as a starting value. At each ramp
step the output is incremented or decremented by 1, unless the number of increments is 0. The time span for
one ramp step is defined with the prescale bit [14] and step-time bits [13:9]. The ramp instruction controls the
eight most-significant bits (MSB) of the PWM values and the remaining bits are interpolated as ramp mid-values
internally for smoother transition.
Prescale = 0 sets a 0.49-ms cycle time and prescale = 1 sets a 15.6-ms cycle time; so the minimum time span
for one step is 0.49 ms (prescale × step time span = 0.49 ms × 1) and the maximum time span is 15.6 ms × 31 =
484 ms/step. If all the step-time bits [13:9] are set to zero, the output value is incremented or decremented during
one prescale on the whole time cycle.
The number-of-increments value defines how many steps are taken during one ramp instruction: the increment
maximum value is 255, which corresponds to an increment from zero value to the maximum value. If PWM
reaches the minimum or maximum value (0 or 255) during the ramp instruction, the ramp instruction is executed
to the end regardless of saturation. This enables ramp instruction to be used as a combined ramp-and-wait
instruction. Note: the ramp instruction is a wait instruction when the increment bits [7:0] are set to zero.
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Programming ramps with variables is very similar to programming ramps with numerical operands. The only
difference is that step time and number of increments are captured from variable registers when the instruction
execution is started. If the variables are updated after starting the instruction execution, it has no effect on
instruction execution. Again, at each ramp step the output is incremented or decremented by 1 unless the step
time is 0 or the number of increments is 0. The time span for one step is defined with the prescale and step-time
bits. The step time is defined with variable A, B, C, or D. Variable A is set by an I2C write to the engine 1, 2, or 3
variable A register or the ld instruction, variables B and C are set with the ld instruction, and variable D is set by
an I2C write to the variable D register.
Setting the EXP_EN bit of registers 07h–0Fh high or low sets the exponential (1) or linear ramp (0). By using the
exponential ramp setting, the visual effect appears like a linear ramp to the human eye.
表 9. Ramp Instructions
Bit
[15]
Bit
[14]
Bit
[13]
Bit
[12]
Bit
[11]
Bit
[10]
Bit
[9]
Bit
[8]
Bit
[7]
Bit
[6]
Bit
[5]
Bit
[4]
Bit
[3]
Bit
[2]
Bit
[1]
Bit
[0]
INST.
ramp(1)
ramp(1)
pre-
scale
0
1
step time
0
sign
no. of increments
no.-of-
increments
variable
pre-
scale
step-time
variable
0
0
0
1
0
0
0
0
sign
(1) Compatible with LP5523 and LP55231
PARAMETER
NAME
NUMERIC OR
VARIABLE
VALUE (d)
DESCRIPTION
0
1
32.7 kHz / 16 ≥ 0.488 ms cycle time
32.7 kHz / 512 ≥ 15.625 ms cycle time
Increase PWM output
prescale
sign
Numeric
Numeric
0
1
Decrease PWM output
Numeric
Variable
1–31
One ramp increment done is in step time × prescale.
Value in the variable A, B, C, or D must be from 1 to 31 for correct
operation.
step time
0–3
Numeric
Variable
0–255
0–3
no. of
increments
The number of ramp cycles. Variables A to D as input.
8.5.2.4.2 Ramp Instruction Application Example
An example of generating a 1.5-s ramp from PWM value 140 (approximately 55%) to 148 (approximately 58%).
The ramp instruction uses relative values, so in this example we must ramp 8 steps up, as shown in 图 25. The
parameters for the RAMP instruction are:
•
•
•
•
•
Positive ramp → sign = 0 (increase by 1)
Step from 140 to 148 → no. of increments = 8
Ramp time 1.5 s → 1.5 s / 8 steps = 187.5 ms/step
Prescale = 1 → 15.625 ms cycle time
187.5 ms / 15.625 ms = 12 → step time = 12
DIMMING
CONTROL
148
147
STEP TIME
SPAN =
187.5 ms
146
145
144
143
142
141
140
RAMP
INSTRUCTION
1500
8
TIME ELAPSED (ms)
STEP COUNT
375
0
750
1125
6
0
1
2
3
4
5
7
图 25. Example of Ramp Instruction
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8.5.2.4.3 Set_PWM
This instruction is used for setting the PWM value on outputs LED0 to LED8 without any ramps. Set the PWM
output value from 0 to 255 with PWM value bits [7:0]. Instruction execution takes 16 32-kHz clock cycles
(= 488 µs).
NAME
PWM value(1)
VALUE (d)
DESCRIPTION
0–255
PWM output duty cycle 0–100%
0 = local variable A
1 = local variable B
variable(2)
0–3
2 = global variable C
3 = global variable D
(1) Valid for numerical operands
(2) Valid for variables
8.5.2.4.4 Wait
When a wait instruction is executed, the engine is set in wait status, and the PWM values on the outputs are
frozen. Note: A wait instruction with prescale and time = 0 is invalid and is executed as rst.
NAME
VALUE (d)
DESCRIPTION
0
1
Divide master clock (32.7 kHz) by 16 which means 0.488 ms cycle time.
Divide master clock (32.7 kHz) by 512 which means 15.625 ms cycle time.
Total wait time is = (time) × (prescale). Maximum 484 ms, minimum 0.488 ms.
prescale
time
1–31
8.5.2.5 LED Mapping Instructions
These instructions define the engine-to-LED mapping. The mapping information is stored in a table, which is
stored in the lower half of SRAM (program memory of the LP5569 device). The LP5569 device has three
program execution engines which can be mapped to nine LED drivers. One engine can control one or multiple
LED drivers. Execution engine 1 has priority over execution engines 2 and 3, with execution engine 2 having
priority over execution engine 3. If an LED is mapped to more than one execution engine, the higher-priority
engine controls the LED.
LED mapping instructions can be divided to two groups:
•
•
Instructions that activate LED mapping to a certain row of the table (map_ instructions).
Instructions that DO NOT activate the actual LED mapping but just shift the mapping-table pointer (load_
instructions).
Activating instructions are map_start, map_sel, map_clr, map_next, map_prev and map_addr. Instructions
load_start, load_end, load_next, load_prev and load_addr do not activate the LED mapping. Mapping table and
master fader bits can be read from I2C registers 70h–75h but are written only via engine instructions.
When an engine is actively mapped to the LEDs, the engine takes over the LED PWM control, and PWM control
registers have no effect. Register control is returned when the engine is mapped to another LED. See 图 26 for a
simplified diagram of LED-engine data flow. The engine does not push a new PWM value to the LED driver
output before the set_pwm or ramp instruction is executed. If the mapping has been released from an LED, the
value in the PWM register still controls the LED brightness, and the PWM register value remains in the last
engine state.
Actual PWM control resolution of the LED engines is 12 bits, but only the 8 highest bits are visible in the I2C
registers. Also, engine commands use the 8 high bits for control, and the 4 low bits are used for smoother ramps.
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I2C
EN=0/1
8-bit
8-bit [11:4]
PWM Register 0
LED0
LED1
LED2
LED3
LED4
LED5
LED6
LED7
LED8
PWM Register 1
PWM Register 2
PWM Register 3
PWM Register 4
PWM Register 5
PWM Register 6
PWM Register 7
PWM Register 8
12-bit
12-bit
8-bit [11:4]
12-bit PWM
8-bit Current
Engine 1
12-bit
Engine 2
Engine 3
Copyright © 2016, Texas Instruments Incorporated
图 26. LED Data Flow
All LED mapping instructions use the SRAM bit to LEDx pin mapping as shown in 表 10.
表 10. LED Mapping Bits in SRAM
Bit
Bit
Bit
Bit
[12]
Bit
[11] [10]
Bit
Bit
[9]
Bit[7
]
Bit[5
]
Bit [8]
Bit[6]
Bit[4] Bit[3] Bit[2] Bit[1]
Bit 0
[15] [14] [13]
LED
mapping
table in
SRAM
LED
7
LED
5
—
—
—
—
—
—
0
LED8
LED6
LED4 LED3 LED2 LED1 LED0
Bit[9] is to enable master fader control by the engine. If this bit is set to 1 in engine 1, then master fader 1 is
enabled.
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表 11. LP5569 LED Mapping Instructions
Bit
Bit
Bit
Bit
Bit
Bit
Bit
[8]
Bit
[7]
Bit
[5]
Bit
[4]
Bit
(1)
INST.
Bit [9]
Bit [6]
Bit [3] Bit [2]
Bit [0]
[1]
[15] [14] [13] [12] [11] [10]
load_start
map_start
load_end
map_sel
1
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
1
1
0
0
0
1
1
1
1
1
1
1
1
0
0
1
0
0
1
1
1
1
0
1
SRAM addresses 0–127(2)
SRAM addresses 0–127(2)
SRAM addresses 0–127(2)
LED select(3)
map_clr
0
0
1
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
map_next
map_prev
load_next
load_prev
load_addr
map_addr
SRAM addresses 0–127(2)
SRAM addresses 0–127(2)
(1) These instructions are compatible with LP5523 and LP55231 mux_* LED mapping instructions.
(2) Absolute address
(3) Only values 1 through 9 are valid, any other value results in no LED driver selected.
8.5.2.5.1 LOAD_START and LOAD_END
The load_start and load_end instructions define the mapping table locations in SRAM.
NAME
VALUE (d)
DESCRIPTION
SRAM address
0–127
Mapping table start or end address restricted to lower half of memory.
8.5.2.5.2 MAP_START
The map_start instruction defines the mapping table start address in the memory, and the first row of the table is
activated (mapped) at the same time.
NAME
VALUE (d)
DESCRIPTION
SRAM address
0–127
Mapping table start address restricted to lower half of memory.
8.5.2.5.3 MAP_SEL
With the map_sel instruction one, and only one, LED driver can be connected to a program execution engine.
Connecting multiple LEDs to one engine is done with the mapping table. After the mapping has been released
from an LED, the PWM register value still controls the LED brightness.
NAME
VALUE (d)
DESCRIPTION
0 = no drivers selected
1 = LED1 selected
2 = LED1 selected
...
LED select
0–127
9 = LED9 selected
10–127 = no drivers selected
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8.5.2.5.4 MAP_CLR
The map_clr instruction clears engine-to-driver mapping. After the mapping has been released from an LED, the
PWM register value still controls the LED brightness.
8.5.2.5.5 MAP_NEXT
This instruction sets the next row active in the mapping table each time it is called. For example, if the second
row is active at this moment, after the map_next instruction call the third row is active. If the mapping table end
address is reached, activation rolls to the mapping-table start address the next time when the map_next
instruction is called. The engine does not push a new PWM value to the LED driver output before the set_pwm
or ramp instruction is executed. If the mapping has been released from an LED, the value in the PWM register
still controls the LED brightness.
8.5.2.5.6 LOAD_NEXT
Similar to the map_next instruction with the exception that no mapping is set. The index pointer is set to point to
the next row and the engine-to-LED-driver connection is not updated.
8.5.2.5.7 MAP_PREV
This instruction sets the previous row active in the mapping table each time it is called. For example, if the third
row is active at this moment, after the map_prev instruction call the second row is active. If the mapping table
start address is reached, activation rolls to the mapping table end address next time the map_prev instruction is
called. The engine does not push a new PWM value to the LED driver output before the set_pwm or ramp
instruction is executed. If the mapping has been released from an LED, the value in the PWM register still
controls the LED brightness.
8.5.2.5.8 LOAD_PREV
Similar to the map_prev instruction with the exception that no mapping is set. The index pointer is set to point to
the previous row and the engine-to-LED-driver connection is not updated.
8.5.2.5.9 MAP_ADDR
The map_addr instruction sets the index pointer to point to the mapping table row defined by bits [6:0] and sets
the row active. The engine does not push a new PWM value to the LED driver output before the set_pwm or
ramp instruction is executed. If the mapping has been released from an LED, the value in the PWM register still
controls the LED brightness.
NAME
VALUE (d)
DESCRIPTION
SRAM address
0–127
SRAM address containing mapping data restricted to lower half of memory.
8.5.2.5.10 LOAD_ADDR
The load_addr instruction sets the index pointer to point to the mapping table row defined by bits [6:0], but the
row is not set active.
NAME
VALUE (d)
DESCRIPTION
SRAM address
0–127
SRAM address containing mapping data restricted to lower half of memory.
8.5.2.6 Branch Instructions
8.5.2.6.1 BRANCH
The branch instruction is provided for repeating a portion of the program code several times. The branch
instruction loads a step number value to the program counter. A loop count parameter defines how many times
the instructions inside the loop are repeated. The step number is loaded into the PC when the instruction is
executed. The PC is relative to the ENGINEx_PROG_START register setting. The LP5569 device supports
nested looping, that is, a loop inside a loop. The number of nested loops is not limited. The instruction takes 16
32-kHz clock cycles.
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表 12. LP5569 Branch Instructions
Bit
[15]
Bit
[14]
Bit
[13]
Bit
[12]
Bit
[11]
Bit
[10]
Bit
[7]
INST.
Bit [9] Bit [8]
Bit [6] Bit [5] Bit [4] Bit [3] Bit [2] Bit [1] Bit [0]
rst
0
1
1
1
1
0
0
0
1
1
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
branch(1)
branch(2)
int
loop count
step number
0
0
0
0
1
1
0
1
0
0
step number
loop count
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
end
int
reset
wait for trigger
send a trigger
trigger
1
1
1
0
0
ext
trig
ext
trig
X(3)
0
X(3)
E3
0
E2
0
E1
0
X(3)
0
X(3)
E3
0
E2
0
E1
0
trig_clear
1
1
1
1
1
1
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
(4)
Number of instructions to be skipped if
the operation returns true
jne
jl
1
0
0
variable 1
variable 1
variable 1
variable 1
variable 2
variable 2
variable 2
variable 2
Number of instructions to be skipped if
the operation returns true
1
0
1
Number of instructions to be skipped if
the operation returns true
jge
je
1
1
0
Number of instructions to be skipped if
the operation returns true
1
1
1
(1) This opcode is used with numerical operands.
(2) This opcode is used with variables.
(3) X means don't care.
(4) This is a new instruction, not available in LP5523 or LP55231.
NAME
loop count(1)
VALUE (d)
0–63
DESCRIPTION
The number of loops to be done. 0 means an infinite loop.
The step number to be loaded to program counter.
step number
0–127
Selects the variable for loop count value. Loop count is loaded with the value of the variable
defined below.
0 = Local variable A
1 = Local variable B
2 = Global variable C
3 = Global variable D
loop count(2)
0–3
(1) Valid for numerical operands.
(2) Valid for variables.
8.5.2.6.2 INT
Send an interrupt to the processor by pulling the INT pin down and setting the corresponding status bit high.
Interrupts can be cleared by reading the interrupt bits in the ENGINE_STATUS register at address 3Ch.
8.5.2.6.3 RST
The rst instruction resets the program counter register (address 30h, 31h, or 32h) and continues executing the
program from the program the start address defined in register addresses 4Bh–4Dh. The instruction takes 16
32‑kHz clock cycles. Note that default value for all program memory registers is 0000h, which is the rst
instruction.
8.5.2.6.4 END
End program execution. The instruction takes 16 32-kHz clock cycles.
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NAME
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
VALUE (d)
DESCRIPTION
0
No interrupt is sent. PWM register values remain intact.
Reset program counter value to 0 and send interrupt to processor by pulling the INT pin
down and setting the corresponding status bit high to notify that the program has ended.
PWM register values remain intact. Interrupts can be cleared by reading the interrupt bits in
STATUS/INTERRUPT register at address 3Ch.
int
1
0
1
Reset program counter value to 0 and hold. PWM register values remain intact.
reset
Reset program counter value to 0 and hold. PWM register values of the non-mapped
drivers remain. PWM register values of the mapped drivers are set to 0000 0000b.
8.5.2.6.5 TRIGGER and TRIG_CLEAR
The wait-for-trigger or send-a-trigger instruction can be used to synchronize operation between the program
execution engines. Sending a trigger instruction takes 16 32-kHz clock cycles and waiting for a trigger takes at
least 16 32-kHz clock cycles. The receiving engine stores the triggers that have been sent. Received triggers are
cleared by the wait-for-trigger instruction or trig_clear instruction. The wait-for-trigger instruction is executed until
all the defined triggers have been received. (Note: several triggers can be defined in the same instruction.) The
external-trigger input signal must stay low for at least two 32-kHz clock cycles to be executed. The trigger output
signal is three 32-kHz clock cycles long. The external trigger signal is active-low; for example, when a trigger is
sent or received, the pin is pulled to GND. Sending an external trigger is masked; that is, the device which has
sent the trigger does not recognize the trigger it sent. If send and wait external triggers are used on the same
instruction, the send external trigger is executed first, followed by the wait external trigger.
The trig_clear instruction clears pending triggers for a single execution engine. Use this instruction in each
execution engine at the beginning of program execution to clear any pending triggers. Pending triggers are
always cleared whenever the engine mode is in the disabled state or load program to SRAM (see SRAM
Memory).
NAME
VALUE (d)
DESCRIPTION
Wait for trigger from the engine(s). Several triggers can be defined in the same instruction.
Bit [7]: Wait for trigger from engine 1.
Bit [8]: Wait for trigger from engine 2.
Bit [9]: Wait for trigger from engine 3.
wait for trigger
0–31
Bit [12]: Wait for trigger from GPIO/TRIG/INT pin.
Bits [10] and [11] are not used.
Send a trigger to the engine(s). Several triggers can be defined in the same instruction.
Bit [1]: Send trigger to engine 1.
Bit [2]: Send trigger to engine 2.
Bit [3]: Send trigger to engine 3.
send a trigger
0–31
Bit [6]: Send trigger to GPIO/TRIG/INT pin.
Bits [4] and [5]: are not used.
8.5.2.6.6 JNE, JGE, JL, and JE
The LP5569 instruction set includes the following conditional jump instructions: jne (jump if not equal); jge (jump
if greater or equal); jl (jump if less); je (jump if equal). If the condition is true, a certain number of instructions are
skipped (that is, the program jumps forward to a location relative to the present location). If the condition is false,
the next instruction is executed.
NAME
Number of
VALUE (d)
DESCRIPTION
instructions to be
skipped if the
The number of instructions to be skipped when the statement is true.
Note: value 0 means redundant code.
0–31
operation returns true.
Defines the variable to be used in the test:
0 = Local variable A
variable 1
0–3
1 = Local variable B
2 = Global variable C
3 = Global variable D
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NAME
VALUE (d)
DESCRIPTION
Defines the variable to be used in the test:
0 = Local variable A
1 = Local variable B
2 = Global variable C
3 = Global variable D
variable 2
0–3
8.5.2.7 Data Transfer and Arithmetic Instructions
表 13. LP5569 Data Transfer and Arithmetic Instructions
Bit
[15]
Bit
[14]
Bit
[13]
Bit
[12]
Bit
[11]
Bit
[10]
Bit
[7]
INST.
ld
Bit [9] Bit [8]
Bit [6] Bit [5] Bit [4] Bit [3] Bit [2] Bit [1] Bit [0]
target
variable
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
0
0
1
1
1
0
1
1
0
1
8-bit value 0
8-bit value 0
target
variable
add(1)
add(2)
sub(1)
sub(2)
target
variable
0
0
0
0
0
0
0
var 1
var 2
var 2
target
variable
target
variable
1
var 1
(1) This opcode is used with numerical operands
(2) This opcode is used with variables.
8.5.2.7.1 LD
This instruction is used to assign a value into a variable; the previous value in that variable is overwritten. Each
of the engines has two local variables, called A and B. The variable C is a global variable.
NAME
target variable
8-bit value
VALUE (d)
0–2
DESCRIPTION
0 = Variable A
1 = Variable B
2 = Variable C
0–255
Variable value
8.5.2.7.2 ADD
This operator either adds an 8-bit value to the current value of the target variable, or adds the value of variable 1
(A, B, C, or D) to the value of variable 2 (A, B, C, or D) and stores the result in the register of variable A, B, or C.
Variables overflow from 255 to 0.
NAME
8-bit value(1)
VALUE (d)
DESCRIPTION
0–255
The value to be added.
0 = Variable A
1 = Variable B
2 = Variable C
target variable
variable 1(2)
0–2
0–3
0 = Local variable A
1 = Local variable B
2 = Global variable C
3 = Global variable D
0 = Local variable A
1 = Local variable B
2 = Global variable C
3 = Global variable D
variable 2(2)
0–3
(1) Valid for numerical operands.
(2) Valid for variables.
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8.5.2.7.3 SUB
The SUB operator either subtracts an 8-bit value from the current value of the target variable, or subtracts the
value of variable 2 (A, B, C, or D) from the value of variable 1 (A, B, C, or D) and stores the result in the register
of the target variable (A, B, or C). Variables overflow from 0 to 255.
NAME
8-bit value(1)
VALUE (d)
DESCRIPTION
0–255
The value to be subtracted.
0 = Variable A
1 = Variable B
2 = Variable C
target variable
variable 1(2)
0–2
0–3
0 = Local variable A
1 = Local variable B
2 = Global variable C
3 = Global variable D
0 = Local variable A
1 = Local variable B
2 = Global variable C
3 = Global variable D
variable 2(2)
0–3
(1) Valid for numerical operands
(2) Valid for variables
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8.6 Register Maps
8.6.1 LP5569_MAP Registers
Table 14 lists the memory-mapped registers for the LP5569_MAP. All register offset addresses not listed in
Table 14 should be considered as reserved locations and the register contents should not be modified.
Table 14. LP5569_MAP Registers
ADDRESS
0h
ACRONYM
REGISTER NAME
Configuration Register
SECTION
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
CONFIG
1h
LED_ENGINE_CONTROL1
LED_ENGINE_CONTROL2
LED0_CONTROL
LED1_CONTROL
LED2_CONTROL
LED3_CONTROL
LED4_CONTROL
LED5_CONTROL
LED6_CONTROL
LED7_CONTROL
LED8_CONTROL
LED0_PWM
Engine Execution Control Register
Engine Operation Mode Register
LED0 Control Register
LED1 Control Register
LED2 Control Register
LED3 Control Register
LED4 Control Register
LED5 Control Register
LED6 Control Register
LED7 Control Register
LED8 Control Register
LED0 PWM Duty Cycle
LED1 PWM Duty Cycle
LED2 PWM Duty Cycle
LED3 PWM Duty Cycle
LED4 PWM Duty Cycle
LED5 PWM Duty Cycle
LED6 PWM Duty Cycle
LED7 PWM Duty Cycle
LED8 PWM Duty Cycle
LED0 Current Control
2h
7h
8h
9h
Ah
Bh
Ch
Dh
Eh
Fh
16h
17h
18h
19h
1Ah
1Bh
1Ch
1Dh
1Eh
22h
23h
24h
25h
26h
27h
28h
29h
2Ah
2Fh
30h
31h
32h
33h
3Ch
3Dh
3Eh
3Fh
42h
43h
44h
LED1_PWM
LED2_PWM
LED3_PWM
LED4_PWM
LED5_PWM
LED6_PWM
LED7_PWM
LED8_PWM
LED0_CURRENT
LED1_CURRENT
LED2_CURRENT
LED3_CURRENT
LED4_CURRENT
LED5_CURRENT
LED6_CURRENT
LED7_CURRENT
LED8_CURRENT
MISC
LED1 Current Control
LED2 Current Control
LED3 Current Control
LED4 Current Control
LED5 Current Control
LED6 Current Control
LED7 Current Control
LED8 Current Control
I2C, Charge Pump and Clock Configuration
Engine1 Program Counter
Engine2 Program Counter
Engine3 Program Counter
Charge Pump and LED Configuration
Engine 1, 2 & 3 Status
TRIG, INT and CLK Configuration
Global Variable D
ENGINE1_PC
ENGINE2_PC
ENGINE3_PC
MISC2
ENGINE_STATUS
IO_CONTROL
VARIABLE_D
RESET
Software Reset
ENGINE1_VARIABLE_A
ENGINE2_VARIABLE_A
ENGINE3_VARIABLE_A
Engine 1 Local Variable A
Engine 2 Local Variable A
Engine 3 Local Variable A
38
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Table 14. LP5569_MAP Registers (continued)
ADDRESS
46h
47h
48h
4Ah
4Bh
4Ch
4Dh
4Fh
50h
51h
52h
53h
54h
55h
56h
57h
58h
59h
5Ah
5Bh
5Ch
5Dh
5Eh
5Fh
60h
61h
62h
63h
64h
65h
66h
67h
68h
69h
6Ah
6Bh
6Ch
6Dh
6Eh
6Fh
70h
71h
72h
73h
74h
75h
80h
ACRONYM
MASTER_FADER1
REGISTER NAME
Engine 1 Master Fader
SECTION
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
MASTER_FADER2
Engine 2 Master Fader
MASTER_FADER3
Engine 3 Master Fader
MASTER_FADER_PWM
ENGINE1_PROG_START
ENGINE2_PROG_START
ENGINE3_PROG_START
PROG_MEM_PAGE_SELECT
PROGRAM_MEM_00
PROGRAM_MEM_01
PROGRAM_MEM_02
PROGRAM_MEM_03
PROGRAM_MEM_04
PROGRAM_MEM_05
PROGRAM_MEM_06
PROGRAM_MEM_07
PROGRAM_MEM_08
PROGRAM_MEM_09
PROGRAM_MEM_10
PROGRAM_MEM_11
PROGRAM_MEM_12
PROGRAM_MEM_13
PROGRAM_MEM_14
PROGRAM_MEM_15
PROGRAM_MEM_16
PROGRAM_MEM_17
PROGRAM_MEM_18
PROGRAM_MEM_19
PROGRAM_MEM_20
PROGRAM_MEM_21
PROGRAM_MEM_22
PROGRAM_MEM_23
PROGRAM_MEM_24
PROGRAM_MEM_25
PROGRAM_MEM_26
PROGRAM_MEM_27
PROGRAM_MEM_28
PROGRAM_MEM_29
PROGRAM_MEM_30
PROGRAM_MEM_31
ENGINE1_MAPPING1
ENGINE1_MAPPING2
ENGINE2_MAPPING1
ENGINE2_MAPPING2
ENGINE3_MAPPING1
ENGINE3_MAPPING2
PWM_CONFIG
PWM Input Duty Cycle
Engine 1 Program Starting Address
Engine 2 Program Starting Address
Engine 2 Program Starting Address
Program Memory Page Select
MSB 0
LSB 0
MSB 1
LSB 1
MSB 2
LSB 2
MSB 3
LSB 3
MSB 4
LSB 4
MSB 5
LSB 5
MSB 6
LSB 6
MSB 7
LSB 7
MSB 8
LSB 8
MSB 9
LSB 9
MSB 10
LSB 10
MSB 11
LSB 11
MSB 12
LSB 12
MSB 13
LSB 13
MSB 14
LSB 14
MSB 15
LSB 15
Engine 1 LED [8] and Master Fader Mapping
Engine 1 LED [7:0] Mapping
Engine 2 LED [8] and Master Fader Mapping
Engine 2 LED [7:0] Mapping
Engine 3 LED [8] and Master Fader Mapping
Engine 3 LED [7:0] Mapping
PWM Input Configuration
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Table 14. LP5569_MAP Registers (continued)
ADDRESS
81h
ACRONYM
REGISTER NAME
LED [8] Fault Status
SECTION
Go
LED_FAULT1
LED_FAULT2
82h
LED [7:0] Fault Status
Go
83h
GENERAL_FAULT
CP Cap, UVLO and TSD Fault Status
Go
Table 15. Register Access-Type Codes
Access Type
Code
Description
Read Type
R
R
Read
Write Type
W
W
Write
Reset or Default Value
-n
Value after reset or the default
value
8.6.1.1 CONFIG Register (Address = 0h) [reset = 0h]
CONFIG is shown in Figure 27 and described in Table 16.
Return to Summary Table.
Configuration Register
Figure 27. CONFIG Register
7
6
5
4
3
2
1
0
RESERVED
R/W-0h
chip_en
R/W-0h
RESERVED
R/W-0h
Table 16. CONFIG Register Field Descriptions
Bit
7
Field
Type
R/W
R/W
Reset
0h
Description
RESERVED
chip_en
6
0h
0 = LP5569 not enabled (default)
1 = LP5569 enabled
5–0
RESERVED
R/W
0h
Reserved
8.6.1.2 LED_ENGINE_CONTROL1 Register (Address = 1h) [reset = 0h]
LED_ENGINE_CONTROL1 is shown in Figure 28 and described in Table 17.
Return to Summary Table.
LED Engine Control Register 1
Execution states are defined in this register, and they are only applicable when the corresponding mode register
in LED_ENGINE_CONTROL2 is set to the run mode. Execution-state values may be written by the host in other
modes, but the engine disregards the write until the mode changes to run mode. The fields in this register define
how the program is executed out of SRAM:
HOLD: The engine does not execute any instructions, but the program counter holds its current value unless
overwritten by the host. This is the only state in which the PC can be written.
STEP: Executes a single instruction, increments the PC, and then changes to the hold state. If the instruction is a
ramp or wait, the engine waits for this instruction to complete before changing to the hold state.
FREE RUN: The engine begins instruction execution from the current value of the PC. The program counter is
reset to zero when its upper-limit value is reached at the top of SRAM memory.
EXECUTE ONCE: Executes a single instruction and then changes to the hold state. The PC remains unaffected
unless the instruction is a branch command, in which case it changes if the branch is taken. If the instruction is a
ramp or wait, it waits for this instruction to complete before changing to hold state.
40
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Figure 28. LED_ENGINE_CONTROL1 Register
7
6
5
4
3
2
1
0
ch1_exec
ch2_exec
R/W-0h
ch3_exec
R/W-0h
RESERVED
R/W-0h
R/W-0h
Table 17. LED_ENGINE_CONTROL1 Register Field Descriptions
Bit
Field
Type
Reset
Description
7–6
ch1_exec
R/W
0h
Engine 1 program execution control
00 = Hold: PC can be read or written only in this mode. (default)
01 = Step. Execute one instruction and return to hold mode.
10 = Free run. Start program from PC.
11 = Execute once. Execute one instruction but don't increment PC.
5–4
3–2
1–0
ch2_exec
ch3_exec
R/W
R/W
R/W
0h
0h
0h
Engine 2 program execution control
00 = Hold: PC can be read or written only in this mode. (default)
01 = Step. Execute one instruction and return to hold mode.
10 = Free run. Start program from PC.
11 = Execute once. Execute one instruction but don't increment PC.
Engine 3 program execution control
00 = Hold: PC can be read or written only in this mode. (default)
01 = Step. Execute one instruction and return to hold mode.
10 = Free run. Start program from PC.
11 = Execute once. Execute one instruction but don't increment PC.
RESERVED
8.6.1.3 LED_ENGINE_CONTROL2 Register (Address = 2h) [reset = 0h]
LED_ENGINE_CONTROL2 is shown in Figure 29 and described in Table 18.
Return to Summary Table.
LED Engine Control Register 2
Operation modes are defined in this register.
DISABLED: Engines each can be configured to be disabled independently. When disabled, the program counter
per ENGINEx_PC is set to 0 and the engine does not execute instructions.
LOAD PROGRAM: Writing to program memory is allowed only when the engine is in the load-program operation
mode and the engine-busy bit (register 3C) is not set. The host should check the engine-busy bit before writing to
program memory or allow at a least 1-ms delay after entering the load mode before memory write, to ensure
initialization. If any engine is set to the load-program mode, then the other engines should be set either to the
disabled or load-program mode, because they are inhibited from executing instructions while loading the SRAM.
The load-program mode also resets the program counter of the respective engine. The load-program mode can
only be entered from the disabled mode.
RUN PROGRAM: The run-program mode executes the instructions stored in the program memory. Execution
register (LED_ENGINE_CONTROL1) bits define how the program is executed (hold, step, free-run or execute
once).
HALT: Instruction execution aborts immediately and engine operation halts.
Figure 29. LED_ENGINE_CONTROL2 Register
7
6
5
4
3
2
1
0
ch1_mode
R/W-0h
ch2_mode
R/W-0h
ch3_mode
R/W-0h
RESERVED
R/W-0h
Table 18. LED_ENGINE_CONTROL2 Register Field Descriptions
Bit
7–6
Field
Type
Reset
Description
ch1_mode
R/W
0h
Engine 1 operation mode
00 = Disabled (default)
01 = Load program to SRAM
10 = Run program
11 = Halt
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Table 18. LED_ENGINE_CONTROL2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
5–4
ch2_mode
R/W
0h
Engine 2 operation mode
00 = Disabled (default)
01 = Load program to SRAM
10 = Run program
11 = Halt
3–2
1–0
ch3_mode
R/W
R/W
0h
0h
Engine 3 operation mode
00 = Disabled (default)
01 = Load program to SRAM
10 = Run program
11 = Halt
RESERVED
8.6.1.4 LED0_CONTROL Register (Address = 7h) [reset = 0h]
LED0_CONTROL is shown in Figure 30 and described in Table 19.
Return to Summary Table.
LED0 Control Register
Figure 30. LED0_CONTROL Register
7
6
5
4
3
2
1
0
mf_mapping0
led0_ratio_en
exp_en0
external_power
0
RESERVED
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 19. LED0_CONTROL Register Field Descriptions
Bit
Field
Type
Reset
Description
7–5
mf_mapping0
R/W
0h
Master fader mapping select:
0h = No master fading (default)
1h = Master fader1
2h = Master fader2
3h = Master fader3
4h = No master fading
5h = PWM input master fading
6h = No master fading
7h = No master fading
4
3
led0_ratio_en
exp_en0
R/W
R/W
0h
0h
0 = Disables ratiometric dimming (default)
1 = Enables ratiometric dimming
When ratiometric dimming is enabled, the emitted color of an RGB-
LED remains the same regardless of the initial magnitude of the LED
output.
0 = Linear adjustment (default)
1 = Exponential adjustment
This bit is effective for both the program execution engine control
and direct PWM control.
2
external_power0
RESERVED
R/W
R/W
0h
0h
0 = LED is powered by charge pump (default)
1 = LED is powered by external power source
1–0
8.6.1.5 LED1_CONTROL Register (Address = 8h) [reset = 0h]
LED1_CONTROL is shown in Figure 31 and described in Table 20.
Return to Summary Table.
LED1 Control Register
42
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Figure 31. LED1_CONTROL Register
7
6
5
4
3
2
1
0
mf_mapping1
led1_ratio_en
exp_en1
external_power
1
RESERVED
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 20. LED1_CONTROL Register Field Descriptions
Bit
Field
Type
Reset
Description
7–5
mf_mapping1
R/W
0h
Master fader mapping select:
0h = No master fading (default)
1h = Master fader1
2h = Master fader2
3h = Master fader3
4h = No master fading
5h = PWM input master fading
6h = No master fading
7h = No master fading
4
3
led1_ratio_en
exp_en1
R/W
R/W
0h
0h
0 = Disables ratiometric dimming (default)
1 = Enables ratiometric dimming
When ratiometric dimming is enabled, the emitted color of an RGB
LED remains the same regardless of the initial magnitude of the LED
output.
0 = Linear adjustment (default)
1 = Exponential adjustment
This bit is effective for both the program execution engine control
and direct PWM control.
2
external_power1
RESERVED
R/W
R/W
0h
0h
0 = LED is powered by charge pump (default)
1 = LED is powered by external power source
1–0
8.6.1.6 LED2_CONTROL Register (Address = 9h) [reset = 0h]
LED2_CONTROL is shown in Figure 32 and described in Table 21.
Return to Summary Table.
LED2 Control Register
Figure 32. LED2_CONTROL Register
7
6
5
4
3
2
1
0
mf_mapping2
led2_ratio_en
exp_en2
external_power
2
RESERVED
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 21. LED2_CONTROL Register Field Descriptions
Bit
7–5
Field
mf_mapping2
Type
Reset
Description
R/W
0h
Master fader mapping select:
0h = No master fading (default)
1h = Master fader1
2h = Master fader2
3h = Master fader3
4h = No master fading
5h = PWM input master fading
6h = No master fading
7h = No master fading
4
led2_ratio_en
R/W
0h
0 = Disables ratiometric dimming (default)
1 = Enables ratiometric dimming
When ratiometric dimming is enabled, the emitted color of an RGB
LED remains the same regardless of the initial magnitude of the LED
output.
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Table 21. LED2_CONTROL Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
3
exp_en2
R/W
0h
0 = Linear adjustment (default)
1 = Exponential adjustment
This bit is effective for both the program execution engine control
and direct PWM control.
2
external_power2
RESERVED
R/W
R/W
0h
0h
0 = LED is powered by charge pump (default)
1 = LED is powered by external power source
1–0
8.6.1.7 LED3_CONTROL Register (Address = Ah) [reset = 0h]
LED3_CONTROL is shown in Figure 33 and described in Table 22.
Return to Summary Table.
LED3 Control Register
Figure 33. LED3_CONTROL Register
7
6
5
4
3
2
1
0
mf_mapping3
led3_ratio_en
exp_en3
external_power
3
RESERVED
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 22. LED3_CONTROL Register Field Descriptions
Bit
Field
Type
Reset
Description
7–5
mf_mapping3
R/W
0h
Master fader mapping select:
0h = No master fading (default)
1h = Master fader1
2h = Master fader2
3h = Master fader3
4h = No master fading
5h = PWM input master fading
6h = No master fading
7h = No master fading
4
3
led3_ratio_en
exp_en3
R/W
R/W
0h
0h
0 = Disables ratiometric dimming (default)
1 = Enables ratiometric dimming
When ratiometric dimming is enabled, the emitted color of an RGB-
LED remains the same regardless of the initial magnitude of the LED
output.
0 = Linear adjustment (default)
1 = Exponential adjustment
This bit is effective for both the program execution engine control
and direct PWM control.
2
external_power3
RESERVED
R/W
R/W
0h
0h
0 = LED is powered by charge pump (default)
1 = LED is powered by external power source
1–0
8.6.1.8 LED4_CONTROL Register (Address = Bh) [reset = 0h]
LED4_CONTROL is shown in Figure 34 and described in Table 23.
Return to Summary Table.
LED4 Control Register
44
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Figure 34. LED4_CONTROL Register
7
6
5
4
3
2
1
0
mf_mapping4
led4_ratio_en
exp_en4
external_power
4
RESERVED
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 23. LED4_CONTROL Register Field Descriptions
Bit
Field
Type
Reset
Description
7–5
mf_mapping4
R/W
0h
Master fader mapping select:
0h = No master fading (default)
1h = Master fader1
2h = Master fader2
3h = Master fader3
4h = No master fading
5h = PWM input master fading
6h = No master fading
7h = No master fading
4
3
led4_ratio_en
exp_en4
R/W
R/W
0h
0h
0 = Disables ratiometric dimming (default)
1 = Enables ratiometric dimming
When ratiometric dimming is enabled, the emitted color of an RGB
LED remains the same regardless of the initial magnitude of the LED
output.
0 = linear adjustment (default)
1 = exponential adjustment
This bit is effective for both the program execution engine control
and direct PWM control.
2
external_power4
RESERVED
R/W
R/W
0h
0h
0 = LED is powered by charge pump (default)
1 = LED is powered by external power source
1–0
8.6.1.9 LED5_CONTROL Register (Address = Ch) [reset = 0h]
LED5_CONTROL is shown in Figure 35 and described in Table 24.
Return to Summary Table.
LED5 Control Register
Figure 35. LED5_CONTROL Register
7
6
5
4
3
2
1
0
mf_mapping5
led5_ratio_en
exp_en5
external_power
5
RESERVED
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 24. LED5_CONTROL Register Field Descriptions
Bit
7–5
Field
mf_mapping5
Type
Reset
Description
R/W
0h
Master fader mapping select:
0h = No master fading (default)
1h = Master fader1
2h = Master fader2
3h = Master fader3
4h = No master fading
5h = PWM input master fading
6h = No master fading
7h = No master fading
4
led5_ratio_en
R/W
0h
0 = Disables ratiometric dimming (default)
1 = Enables ratiometric dimming
When ratiometric dimming is enabled, the emitted color of an RGB
LED remains the same regardless of the initial magnitude of the LED
output.
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Table 24. LED5_CONTROL Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
3
exp_en5
R/W
0h
0 = Linear adjustment (default)
1 = exponential adjustment
This bit is effective for both the program execution engine control
and direct PWM control.
2
external_power5
RESERVED
R/W
R/W
0h
0h
0 = LED is powered by charge pump (default)
1 = LED is powered by external power source
1–0
8.6.1.10 LED6_CONTROL Register (Address = Dh) [reset = 0h]
LED6_CONTROL is shown in Figure 36 and described in Table 25.
Return to Summary Table.
LED6 Control Register
Figure 36. LED6_CONTROL Register
7
6
5
4
3
2
1
0
mf_mapping6
led6_ratio_en
exp_en6
external_power
6
RESERVED
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 25. LED6_CONTROL Register Field Descriptions
Bit
Field
Type
Reset
Description
7–5
mf_mapping6
R/W
0h
Master fader mapping select:
0h = No master fading (default)
1h = Master fader1
2h = Master fader2
3h = Master fader3
4h = No master fading
5h = PWM input master fading
6h = No master fading
7h = No master fading
4
3
led6_ratio_en
exp_en6
R/W
R/W
0h
0h
0 = Disables ratiometric dimming (default)
1 = Enables ratiometric dimming
When ratiometric dimming is enabled, the emitted color of an
RGBLED remains the same regardless of the initial magnitude of the
LED output.
0 = linear adjustment (default)
1 = exponential adjustment
This bit is effective for both the program execution engine control
and direct PWM control.
2
external_power6
RESERVED
R/W
R/W
0h
0h
0 = LED is powered by charge pump (default)
1 = LED is powered by external power source
1–0
8.6.1.11 LED7_CONTROL Register (Address = Eh) [reset = 0h]
LED7_CONTROL is shown in Figure 37 and described in Table 26.
Return to Summary Table.
LED7 Control Register
46
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Figure 37. LED7_CONTROL Register
7
6
5
4
3
2
1
0
mf_mapping7
led7_ratio_en
exp_en7
external_power
7
RESERVED
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 26. LED7_CONTROL Register Field Descriptions
Bit
Field
Type
Reset
Description
7–5
mf_mapping7
R/W
0h
Master fader mapping select:
0h = No master fading (default)
1h = Master fader1
2h = Master fader2
3h = Master fader3
4h = No master fading
5h = PWM input master fading
6h = No master fading
7h = No master fading
4
3
led7_ratio_en
exp_en7
R/W
R/W
0h
0h
0 = Disables ratiometric dimming (default)
1 = Enables ratiometric dimming
When ratiometric dimming is enabled, the emitted color of an RGB
LED remains the same regardless of the initial magnitude of the LED
output.
0 = Linear adjustment (default)
1 = Exponential adjustment
This bit is effective for both the program execution engine control
and direct PWM control.
2
external_power7
RESERVED
R/W
R/W
0h
0h
0 = LED is powered by charge pump (default)
1 = LED is powered by external power source
1–0
8.6.1.12 LED8_CONTROL Register (Address = Fh) [reset = 0h]
LED8_CONTROL is shown in Figure 38 and described in Table 27.
Return to Summary Table.
LED8 Control Register
Figure 38. LED8_CONTROL Register
7
6
5
4
3
2
1
0
mf_mapping8
led8_ratio_en
exp_en8
external_power
8
RESERVED
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
Table 27. LED8_CONTROL Register Field Descriptions
Bit
7–5
Field
mf_mapping8
Type
Reset
Description
R/W
0h
Master fader mapping select:
0h = No master fading (default)
1h = Master fader1
2h = Master fader2
3h = Master fader3
4h = No master fading
5h = PWM input master fading
6h = No master fading
7h = No master fading
4
led8_ratio_en
R/W
0h
0 = Disables ratiometric dimming (default)
1 = Enables ratiometric dimming
When ratiometric dimming is enabled, the emitted color of an RGB
LED remains the same regardless of the initial magnitude of the LED
output.
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Table 27. LED8_CONTROL Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
3
exp_en8
R/W
0h
0 = Linear adjustment (default)
1 = Exponential adjustment
This bit is effective for both the program execution engine control
and direct PWM control.
2
external_power8
RESERVED
R/W
R/W
0h
0h
0 = LED is powered by charge pump (default)
1 = LED is powered by external power source
1–0
8.6.1.13 LED0_PWM Register (Address = 16h) [reset = 0h]
LED0_PWM is shown in Figure 39 and described in Table 28.
Return to Summary Table.
LED0 PWM Register
This is the PWM duty cycle control for the LED0 output.
Figure 39. LED0_PWM Register
7
6
5
4
3
2
1
0
pwm0
R/W-0h
Table 28. LED0_PWM Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
pwm0
R/W
0h
00h = 0% duty cycle (default)
...
80h = 50% duty cycle
...
FFh = 100% duty cycle
8.6.1.14 LED1_PWM Register (Address = 17h) [reset = 0h]
LED1_PWM is shown in Figure 40 and described in Table 29.
Return to Summary Table.
LED1 PWM Register
This is the PWM duty cycle control for the LED1 output.
Figure 40. LED1_PWM Register
7
6
5
4
3
2
1
0
pwm1
R/W-0h
Table 29. LED1_PWM Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
pwm1
R/W
0h
00h = 0% duty cycle (default)
...
80h = 50% duty cycle
...
FFh = 100% duty cycle
48
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8.6.1.15 LED2_PWM Register (Address = 18h) [reset = 0h]
LED2_PWM is shown in Figure 41 and described in Table 30.
Return to Summary Table.
LED2 PWM Register
This is the PWM duty cycle control for the LED2 output.
Figure 41. LED2_PWM Register
7
6
5
4
3
2
1
1
1
0
0
0
pwm2
R/W-0h
Table 30. LED2_PWM Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
pwm2
R/W
0h
00h = 0% duty cycle (default)
...
80h = 50% duty cycle
...
FFh = 100% duty cycle-
8.6.1.16 LED3_PWM Register (Address = 19h) [reset = 0h]
LED3_PWM is shown in Figure 42 and described in Table 31.
Return to Summary Table.
LED3 PWM Register
This is the PWM duty cycle control for the LED3 output.
Figure 42. LED3_PWM Register
7
6
5
4
3
2
pwm3
R/W-0h
Table 31. LED3_PWM Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
pwm3
R/W
0h
00h = 0% duty cycle (default)
...
80h = 50% duty cycle
...
FFh = 100% duty cycle
8.6.1.17 LED4_PWM Register (Address = 1Ah) [reset = 0h]
LED4_PWM is shown in Figure 43 and described in Table 32.
Return to Summary Table.
LED4 PWM Register
This is the PWM duty cycle control for the LED4 output.
Figure 43. LED4_PWM Register
7
6
5
4
3
2
pwm4
R/W-0h
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Table 32. LED4_PWM Register Field Descriptions
Bit
Field
Type
Reset
Description
7–0
pwm4
R/W
0h
00h = 0% duty cycle (default)
,,,
80h = 50% duty cycle
...
FFh = 100% duty cycle
8.6.1.18 LED5_PWM Register (Address = 1Bh) [reset = 0h]
LED5_PWM is shown in Figure 44 and described in Table 33.
Return to Summary Table.
LED5 PWM Register
This is the PWM duty cycle control for the LED5 output.
Figure 44. LED5_PWM Register
7
6
5
4
3
2
1
0
pwm5
R/W-0h
Table 33. LED5_PWM Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
pwm5
R/W
0h
00h = 0% duty cycle (default)
...
80h = 50% duty cycle
...
FFh = 100% duty cycle
8.6.1.19 LED6_PWM Register (Address = 1Ch) [reset = 0h]
LED6_PWM is shown in Figure 45 and described in Table 34.
Return to Summary Table.
LED6 PWM Register
This is the PWM duty cycle control for the LED6 output.
Figure 45. LED6_PWM Register
7
6
5
4
3
2
1
0
pwm6
R/W-0h
Table 34. LED6_PWM Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
pwm6
R/W
0h
00h = 0% duty cycle (default)
...
80h = 50% duty cycle
...
FFh = 100% duty cycle
8.6.1.20 LED7_PWM Register (Address = 1Dh) [reset = 0h]
LED7_PWM is shown in Figure 46 and described in Table 35.
Return to Summary Table.
LED7 PWM Register
50
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This is the PWM duty cycle control for the LED7 output.
Figure 46. LED7_PWM Register
7
6
5
4
3
2
1
0
pwm7
R/W-0h
Table 35. LED7_PWM Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
pwm7
R/W
0h
00h = 0% duty cycle (default)
...
80h = 50% duty cycle
...
FFh = 100% duty cycle
8.6.1.21 LED8_PWM Register (Address = 1Eh) [reset = 0h]
LED8_PWM is shown in Figure 47 and described in Table 36.
Return to Summary Table.
LED8 PWM Register
This is the PWM duty cycle control for the LED8 output.
Figure 47. LED8_PWM Register
7
6
5
4
3
2
1
0
pwm8
R/W-0h
Table 36. LED8_PWM Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
pwm8
R/W
0h
00h = 0% duty cycle (default)
...
80h = 50% duty cycle
...
FFh = 100% duty cycle
8.6.1.22 LED0_CURRENT Register (Address = 22h) [reset = AFh]
LED0_CURRENT is shown in Figure 48 and described in Table 37.
Return to Summary Table.
LED0 Current Register
LED0 driver output current control register. The resolution is 8 bits, and step size is 100 μA.
Figure 48. LED0_CURRENT Register
7
6
5
4
3
2
1
0
current0
R/W-AFh
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Table 37. LED0_CURRENT Register Field Descriptions
Bit
Field
Type
Reset
Description
7–0
current0
R/W
AFh
00h = 0.0 mA
01h = 0.1 mA
...
AFh = 17.5 mA (default)
...
FFh = 25.5 mA
8.6.1.23 LED1_CURRENT Register (Address = 23h) [reset = AFh]
LED1_CURRENT is shown in Figure 49 and described in Table 38.
Return to Summary Table.
LED1 Current Register
LED1 driver output current control register. The resolution is 8 bits, and step size is 100 μA.
Figure 49. LED1_CURRENT Register
7
6
5
4
3
2
1
0
current1
R/W-AFh
Table 38. LED1_CURRENT Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
current1
R/W
AFh
00h = 0.0 mA
01h = 0.1 mA
...
AFh = 17.5 mA (default)
...
FFh = 25.5 mA
8.6.1.24 LED2_CURRENT Register (Address = 24h) [reset = AFh]
LED2_CURRENT is shown in Figure 50 and described in Table 39.
Return to Summary Table.
LED2 Current Register
LED2 driver output current control register. The resolution is 8 bits, and step size is 100 μA.
Figure 50. LED2_CURRENT Register
7
6
5
4
3
2
1
0
current2
R/W-AFh
Table 39. LED2_CURRENT Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
current2
R/W
AFh
00h = 0.0 mA
01h = 0.1 mA
...
AFh = 17.5 mA (default)
...
FFh = 25.5 mA
52
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8.6.1.25 LED3_CURRENT Register (Address = 25h) [reset = AFh]
LED3_CURRENT is shown in Figure 51 and described in Table 40.
Return to Summary Table.
LED3 Current Register
LED3 driver output current control register. The resolution is 8 bits, and step size is 100 μA.
Figure 51. LED3_CURRENT Register
7
6
5
4
3
2
1
0
current3
R/W-AFh
Table 40. LED3_CURRENT Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
current3
R/W
AFh
00h = 0.0 mA
01h = 0.1 mA
...
AFh = 17.5 mA (default)
...
FFh = 25.5 mA
8.6.1.26 LED4_CURRENT Register (Address = 26h) [reset = AFh]
LED4_CURRENT is shown in Figure 52 and described in Table 41.
Return to Summary Table.
LED4 Current Register
LED4 driver output current control register. The resolution is 8 bits, and step size is 100 μA.
Figure 52. LED4_CURRENT Register
7
6
5
4
3
2
1
0
current4
R/W-AFh
Table 41. LED4_CURRENT Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
current4
R/W
AFh
00h = 0.0 mA
01h = 0.1 mA
...
AFh = 17.5 mA (default)
...
FFh = 25.5 mA
8.6.1.27 LED5_CURRENT Register (Address = 27h) [reset = AFh]
LED5_CURRENT is shown in Figure 53 and described in Table 42.
Return to Summary Table.
LED5 Current Register
LED5 driver output current control register. The resolution is 8 bits, and step size is 100 μA.
Figure 53. LED5_CURRENT Register
7
6
5
4
3
2
1
0
current5
R/W-AFh
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Table 42. LED5_CURRENT Register Field Descriptions
Bit
Field
Type
Reset
Description
7–0
current5
R/W
AFh
00h = 0.0 mA
01h = 0.1 mA
...
AFh = 17.5 mA (default)
...
FFh = 25.5 mA
8.6.1.28 LED6_CURRENT Register (Address = 28h) [reset = AFh]
LED6_CURRENT is shown in Figure 54 and described in Table 43.
Return to Summary Table.
LED6 Current Register
LED6 driver output current control register. The resolution is 8 bits, and step size is 100 μA.
Figure 54. LED6_CURRENT Register
7
6
5
4
3
2
1
0
current6
R/W-AFh
Table 43. LED6_CURRENT Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
current6
R/W
AFh
00h = 0.0 mA
01h = 0.1 mA
...
AFh = 17.5 mA (default)
...
FFh = 25.5 mA
8.6.1.29 LED7_CURRENT Register (Address = 29h) [reset = AFh]
LED7_CURRENT is shown in Figure 55 and described in Table 44.
Return to Summary Table.
LED7 Current Register
LED7 driver output current control register. The resolution is 8 bits, and step size is 100 μA.
Figure 55. LED7_CURRENT Register
7
6
5
4
3
2
1
0
current7
R/W-AFh
Table 44. LED7_CURRENT Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
current7
R/W
AFh
00h = 0.0 mA
01h = 0.1 mA
...
AFh = 17.5 mA (default)
...
FFh = 25.5 mA
54
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8.6.1.30 LED8_CURRENT Register (Address = 2Ah) [reset = AFh]
LED8_CURRENT is shown in Figure 56 and described in Table 45.
Return to Summary Table.
LED8 Current Register
LED8 driver output current control register. The resolution is 8 bits, and step size is 100 μA.
Figure 56. LED8_CURRENT Register
7
6
5
4
3
2
1
0
current8
R/W-AFh
Table 45. LED8_CURRENT Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
current8
R/W
AFh
00h = 0.0 mA
01h = 0.1 mA
...
AFh = 17.5 mA (default)
...
FFh = 25.5 mA
8.6.1.31 MISC Register (Address = 2Fh) [reset = 40h]
MISC is shown in Figure 57 and described in Table 46.
Return to Summary Table.
Miscellaneous Register
Figure 57. MISC Register
7
6
5
4
3
2
1
0
RESERVED
R/W-0h
en_auto_incr
R/W-1h
powersave_en
R/W-0h
cp_mode
R/W-0h
cp_return_1x
R/W-0h
RESERVED
R/W-0h
int_clk_en
R/W-0h
Table 46. MISC Register Field Descriptions
Bit
7
Field
Type
R/W
R/W
Reset
0h
Description
RESERVED
en_auto_incr
Reserved
I2C address auto-increment enable
6
1h
0 = Address auto-increment is disabled
1 = Address auto-increment is enabled (default)
5
powersave_en
cp_mode
R/W
R/W
0h
0h
Power-save mode enable select
0 = Power-save mode is disabled (default)
1 = Power-save mode is enabled
4–3
Charge-pump mode selection
00 = Disabled (cp output pulled-down internally, default)
01 = 1× mode
10 = 1.5× mode
11 = Auto mode
2
1
cp_return_1x
RESERVED
R/W
R/W
0h
0h
Charge-pump return to 1× mode select
0 = Charge-pump mode is not affected during shutdown or power-
save entry (default)
1 = Charge-pump mode is forced to 1x mode during shutdown or
power-save entry
Reserved
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Table 46. MISC Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
0
int_clk_en
R/W
0h
Internal 32-kHz clock-enable select
0 = External 32-kHz clock is used from CLK input pin (default)
1 = Internal 32-kHz oscillator is enabled
Note: This bit is STATIC and should only be changed when
CONFIG.CHIP_EN = 0.
8.6.1.32 ENGINE1_PC Register (Address = 30h) [reset = 0h]
ENGINE1_PC is shown in Figure 58 and described in Table 47.
Return to Summary Table.
Engine1 Program Counter Register
Figure 58. ENGINE1_PC Register
7
6
5
4
3
2
1
0
engine1_pc
R/W-0h
Table 47. ENGINE1_PC Register Field Descriptions
Bit
7–0
Field
engine1_pc
Type
Reset
Description
Program counter starting value for program execution engine 1.
R/W
0h
8.6.1.33 ENGINE2_PC Register (Address = 31h) [reset = 0h]
ENGINE2_PC is shown in Figure 59 and described in Table 48.
Return to Summary Table.
Engine2 Program Counter Register
Figure 59. ENGINE2_PC Register
7
6
5
4
3
2
1
0
engine2_pc
R/W-0h
Table 48. ENGINE2_PC Register Field Descriptions
Bit
7–0
Field
engine2_pc
Type
Reset
Description
Program counter starting value for program execution engine 2.
R/W
0h
8.6.1.34 ENGINE3_PC Register (Address = 32h) [reset = 0h]
ENGINE3_PC is shown in Figure 60 and described in Table 49.
Return to Summary Table.
Engine3 Program Counter Register
Figure 60. ENGINE3_PC Register
7
6
5
4
3
2
1
0
engine3_pc
R/W-0h
56
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Table 49. ENGINE3_PC Register Field Descriptions
Bit
Field
Type
Reset
Description
Program counter starting value for program execution engine 3.
7–0
engine3_pc
R/W
0h
8.6.1.35 MISC2 Register (Address = 33h) [reset = 2h]
MISC2 is shown in Figure 61 and described in Table 50.
Return to Summary Table.
Miscellaneous Register 2
Figure 61. MISC2 Register
7
6
5
4
3
2
1
0
RESERVED
R/W-0h
led_short_test
R/W-0h
led_open_test
R/W-0h
led_headroom
R/W-1h
cp_dis_disch
R/W-0h
Table 50. MISC2 Register Field Descriptions
Bit
Field
Type
R/W
R/W
Reset
0h
Description
7–5
4
RESERVED
Reserved
led_short_test
0h
0 = LED-short test disabled (default)
1 = LED-short test enabled
3
led_open_test
led_headroom
R/W
R/W
0h
1h
0 = LED-open test disabled (default)
1 = LED-open test enabled
2–1
Selectable low-headroom comparator settings:
00 = 200 mV
01 = 250 mV (default)
10 = 300 mV
11 = 250 mV
0
cp_dis_disch
R/W
0h
Charge pump discharge disable.
0 = discharging is enabled in shutdown and standby states, absent
of TSD. (default)
1 = discharging is disabled
8.6.1.36 ENGINE_STATUS Register (Address = 3Ch) [reset = 80h]
ENGINE_STATUS is shown in Figure 62 and described in Table 51.
Return to Summary Table.
Engine Status Register
Figure 62. ENGINE_STATUS Register
7
6
5
4
3
2
1
0
mask_busy
R/W-1h
startup_busy
R-0h
engine_busy
R-0h
RESERVED
R-0h
ch3_int
R-0h
ch2_int
R-0h
ch1_int
R-0h
Table 51. ENGINE_STATUS Register Field Descriptions
Bit
Field
mask_busy
Type
Reset
Description
7
R/W
1h
Mask bit for interrupts generated by START-UP_BUSY or
ENGINE_BUSY.
0 = External interrupt is generated when START-UP_BUSY or
ENGINE_BUSY condition is no longer true.
1 = Interrupt events are masked (no external interrupt generated by
START-UP_BUSY or ENGINE_BUSY).
Reading register 3Ch clears the status bits and releases the INT pin
to the high state.
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Table 51. ENGINE_STATUS Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
6
startup_busy
R
0h
A status bit which indicates that the device is running the internal
start-up sequence.
0 = Internal start-up sequence completed.
1 = Internal start-up sequence running
5
engine_busy
R
0h
A status bit which indicates that a program execution engine is
clearing internal registers. Serial bus master should not write or read
program memory, or registers 30h to 32h or 4Bh to 4Dh, when this
bit is set to 1.
0 = All engines ready
1 = At least one of the engines is clearing internal registers.
4–3
2
RESERVED
ch3_int
R
R
0h
0h
Reserved
Engine3 interrupt.
0 = Interrupt cleared
1 = Interrupt set
Interrupt is set by the END or INT instruction. Reading the
ENGINE_STATUS address clears the interrupt.
1
0
ch2_int
ch1_int
R
R
0h
0h
Engine2 interrupt.
0 = Interrupt cleared
1 = Interrupt set
Interrupt is set by the END or INT instruction. Reading the
ENGINE_STATUS address clears the interrupt.
Engine1 interrupt.
0 = Interrupt cleared
1 = Interrupt set
Interrupt is set by the END or INT instruction. Reading the
ENGINE_STATUS address clears the interrupt.
8.6.1.37 IO_CONTROL Register (Address = 3Dh) [reset = 2h]
IO_CONTROL is shown in Figure 63 and described in Table 52.
Return to Summary Table.
I/O Control Register
Figure 63. IO_CONTROL Register
7
6
5
4
3
2
1
0
RESERVED
R/W-0h
en_clk_out
R/W-0h
gpio_config
R/W-1h
gpo
R/W-0h
Table 52. IO_CONTROL Register Field Descriptions
Bit
Field
Type
R/W
R/W
Reset
0h
Description
7–4
3
RESERVED
en_clk_out
0h
0 = CLK pin is an input (default)
1 = CLK pin is an output driven by the internal 32-kHz oscillator
2–1
gpio_config
R/W
1h
GPIO configuration
00 = Trigger for LED engines
01 = Interrupt from LED engines (default)
10 = GPO register bit controlled by I2C (output only)
11 = GPO register bit controlled by I2C (output only)
0
gpo
R/W
0h
GPIO pin control when gpio_config = 10 or 11
0 = GPIO/TRIG/INT pin Low
1 = GPIO/TRIG/INT pin High
58
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8.6.1.38 VARIABLE_D Register (Address = 3Eh) [reset = 0h]
VARIABLE_D is shown in Figure 64 and described in Table 53.
Return to Summary Table.
Variable D Register
Figure 64. VARIABLE_D Register
7
6
5
4
3
2
1
0
variable_d
R/W-0h
Table 53. VARIABLE_D Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
variable_d
R/W
0h
These bits are used for storing a global 8-bit variable. The variable
can be used to control program flow.
8.6.1.39 RESET Register (Address = 3Fh) [reset = 0h]
RESET is shown in Figure 65 and described in Table 54.
Return to Summary Table.
Reset Register
Figure 65. RESET Register
7
6
5
4
3
2
1
0
reset
W-0h
Table 54. RESET Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
reset
W
0h
Writing FFh into this register resets the device. Internal registers are
reset to the default values. Reading this register returns 0h.
8.6.1.40 ENGINE1_VARIABLE_A Register (Address = 42h) [reset = 0h]
ENGINE1_VARIABLE_A is shown in Figure 66 and described in Table 55.
Return to Summary Table.
Engine1 Variable A Register
Figure 66. ENGINE1_VARIABLE_A Register
7
6
5
4
3
2
1
0
engine1_variable_a
R/W-0h
Table 55. ENGINE1_VARIABLE_A Register Field Descriptions
Bit
7–0
Field
engine1_variable_a
Type
Reset
Description
These bits are used for the engine 1 local variable.
R/W
0h
8.6.1.41 ENGINE2_VARIABLE_A Register (Address = 43h) [reset = 0h]
ENGINE2_VARIABLE_A is shown in Figure 67 and described in Table 56.
Return to Summary Table.
Engine2 Variable A
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Figure 67. ENGINE2_VARIABLE_A Register
7
6
5
4
3
2
1
0
engine2_variable_a
R/W-0h
Table 56. ENGINE2_VARIABLE_A Register Field Descriptions
Bit
7–0
Field
engine2_variable_a
Type
Reset
Description
These bits are used for the engine 2 local variable.
R/W
0h
8.6.1.42 ENGINE3_VARIABLE_A Register (Address = 44h) [reset = 0h]
ENGINE3_VARIABLE_A is shown in Figure 68 and described in Table 57.
Return to Summary Table.
Engine3 Variable A
Figure 68. ENGINE3_VARIABLE_A Register
7
6
5
4
3
2
1
0
engine3_variable_a
R/W-0h
Table 57. ENGINE3_VARIABLE_A Register Field Descriptions
Bit
7–0
Field
engine3_variable_a
Type
Reset
Description
These bits are used for the engine 3 local variable.
R/W
0h
8.6.1.43 MASTER_FADER1 Register (Address = 46h) [reset = 0h]
MASTER_FADER1 is shown in Figure 69 and described in Table 58.
Return to Summary Table.
Master Fader1 Register
An 8-bit register to control all the LED outputs mapped to MASTER FADER1. The master fader allows the user
to control dimming of multiple LEDS with a single serial bus write.
Figure 69. MASTER_FADER1 Register
7
6
5
4
3
2
1
0
master_fader1
R/W-0h
Table 58. MASTER_FADER1 Register Field Descriptions
Bit
7–0
Field
master_fader1
Type
Reset
Description
R/W
0h
Master fader1 is controlled by engine1.
8.6.1.44 MASTER_FADER2 Register (Address = 47h) [reset = 0h]
MASTER_FADER2 is shown in Figure 70 and described in Table 59.
Return to Summary Table.
Master Fader2 Register
An 8-bit register to control all the LED outputs mapped to MASTER FADER2. Master fader allows the user to
control dimming of multiple LEDS with a single serial bus write.
60
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Figure 70. MASTER_FADER2 Register
7
6
5
4
3
2
1
0
master_fader2
R/W-0h
Table 59. MASTER_FADER2 Register Field Descriptions
Bit
Field
master_fader2
Type
Reset
Description
7–0
R/W
0h
Master fader2 is controlled by engine 2.
8.6.1.45 MASTER_FADER3 Register (Address = 48h) [reset = 0h]
MASTER_FADER3 is shown in Figure 71 and described in Table 60.
Return to Summary Table.
Master Fader3 Register
An 8-bit register to control all the LED outputs mapped to MASTER FADER2. Master fader allows the user to
control dimming of multiple LEDS with a single serial bus write.
Figure 71. MASTER_FADER3 Register
7
6
5
4
3
2
1
0
master_fader3
R/W-0h
Table 60. MASTER_FADER3 Register Field Descriptions
Bit
7–0
Field
master_fader3
Type
Reset
Description
R/W
0h
Master fader3 is controlled by engine 3.
8.6.1.46 MASTER_FADER_PWM Register (Address = 4Ah) [reset = 0h]
MASTER_FADER_PWM is shown in Figure 72 and described in Table 61.
Return to Summary Table.
Master Fader PWM Register
Figure 72. MASTER_FADER_PWM Register
7
6
5
4
3
2
1
0
master_fader_pwm
R-0h
Table 61. MASTER_FADER_PWM Register Field Descriptions
Bit
7–0
Field
master_fader_pwm
Type
Reset
Description
R
0h
PWM input duty cycle. See 图 14.
8.6.1.47 ENGINE1_PROG_START Register (Address = 4Bh) [reset = 0h]
ENGINE1_PROG_START is shown in Figure 73 and described in Table 62.
Return to Summary Table.
Engine1 Program Start Register
Figure 73. ENGINE1_PROG_START Register
7
6
5
4
3
2
1
0
prog_start_addr1
R/W-0h
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Table 62. ENGINE1_PROG_START Register Field Descriptions
Bit
Field
Type
Reset
Description
7–0
prog_start_addr1
R/W
0h
Engine 1 program start address.
8.6.1.48 ENGINE2_PROG_START Register (Address = 4Ch) [reset = 0h]
ENGINE2_PROG_START is shown in Figure 74 and described in Table 63.
Return to Summary Table.
Engine2 Program Start Register
Figure 74. ENGINE2_PROG_START Register
7
6
5
4
3
2
1
0
prog_start_addr2
R/W-0h
Table 63. ENGINE2_PROG_START Register Field Descriptions
Bit
7–0
Field
prog_start_addr2
Type
Reset
Description
R/W
0h
Engine 2 program start address.
8.6.1.49 ENGINE3_PROG_START Register (Address = 4Dh) [reset = 0h]
ENGINE3_PROG_START is shown in Figure 75 and described in Table 64.
Return to Summary Table.
Engine3 Program Start Register
Figure 75. ENGINE3_PROG_START Register
7
6
5
4
3
2
1
0
prog_start_addr3
R/W-0h
Table 64. ENGINE3_PROG_START Register Field Descriptions
Bit
7–0
Field
prog_start_addr3
Type
Reset
Description
R/W
0h
Engine 3 program start address.
8.6.1.50 PROG_MEM_PAGE_SELECT Register (Address = 4Fh) [reset = 0h]
PROG_MEM_PAGE_SELECT is shown in Figure 76 and described in Table 65.
Return to Summary Table.
Program Memory-Page Selection Register
SRAM page select. SRAM is 256 × 16 addressable from I2C, and is viewed as 16 pages of 32 bytes. This
register selects which page is being accessed, serving as the upper bits of the SRAM address. The I2C host
must write this register during the course of loading SRAM contents in order to access the next page.
Figure 76. PROG_MEM_PAGE_SELECT Register
7
6
5
4
3
2
1
0
RESERVED
R/W-0h
page_sel
R/W-0h
62
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Table 65. PROG_MEM_PAGE_SELECT Register Field Descriptions
Bit
7–4
3–0
Field
Type
R/W
R/W
Reset
0h
Description
RESERVED
page_sel
0h
0000 = page 0 (lowest 32 bytes)
0001 = page 1 (bytes 32–63)
...
1111 = page 15 (highest 32 bytes)
8.6.1.51 PROGRAM_MEM_00 Register (Address = 50h) [reset = 0h]
PROGRAM_MEM_00 is shown in Figure 77 and described in Table 66.
Return to Summary Table.
Program Memory 00 Register
Figure 77. PROGRAM_MEM_00 Register
7
6
5
4
3
2
1
1
1
0
0
0
cmd00_msb
R/W-0h
Table 66. PROGRAM_MEM_00 Register Field Descriptions
Bit
7–0
Field
cmd00_msb
Type
Reset
Description
R/W
0h
Program memory data]
8.6.1.52 PROGRAM_MEM_01 Register (Address = 51h) [reset = 0h]
PROGRAM_MEM_01 is shown in Figure 78 and described in Table 67.
Return to Summary Table.
Program Memory 01 Register
Figure 78. PROGRAM_MEM_01 Register
7
6
5
4
3
2
cmd00_lsb
R/W-0h
Table 67. PROGRAM_MEM_01 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd00_lsb
R/W
0h
Program memory data
8.6.1.53 PROGRAM_MEM_02 Register (Address = 52h) [reset = 0h]
PROGRAM_MEM_02 is shown in Figure 79 and described in Table 68.
Return to Summary Table.
Program Memory 02 Register
Figure 79. PROGRAM_MEM_02 Register
7
6
5
4
3
2
cmd01_msb
R/W-0h
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Table 68. PROGRAM_MEM_02 Register Field Descriptions
Bit
Field
Type
Reset
Description
7–0
cmd01_msb
R/W
0h
Program memory data
8.6.1.54 PROGRAM_MEM_03 Register (Address = 53h) [reset = 0h]
PROGRAM_MEM_03 is shown in Figure 80 and described in Table 69.
Return to Summary Table.
Program Memory 03 Register
Figure 80. PROGRAM_MEM_03 Register
7
6
5
4
3
2
1
1
1
0
cmd01_lsb
R/W-0h
Table 69. PROGRAM_MEM_03 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd01_lsb
R/W
0h
Program memory data
8.6.1.55 PROGRAM_MEM_04 Register (Address = 54h) [reset = 0h]
PROGRAM_MEM_04 is shown in Figure 81 and described in Table 70.
Return to Summary Table.
Program Memory 04 Register
Figure 81. PROGRAM_MEM_04 Register
7
6
5
4
3
2
0
cmd02_msb
R/W-0h
Table 70. PROGRAM_MEM_04 Register Field Descriptions
Bit
7–0
Field
cmd02_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.56 PROGRAM_MEM_05 Register (Address = 55h) [reset = 0h]
PROGRAM_MEM_05 is shown in Figure 82 and described in Table 71.
Return to Summary Table.
Program Memory 05 Register
Figure 82. PROGRAM_MEM_05 Register
7
6
5
4
3
2
0
cmd02_lsb
R/W-0h
Table 71. PROGRAM_MEM_05 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd02_lsb
R/W
0h
Program memory data
64
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8.6.1.57 PROGRAM_MEM_06 Register (Address = 56h) [reset = 0h]
PROGRAM_MEM_06 is shown in Figure 83 and described in Table 72.
Return to Summary Table.
Program Memory 06 Register
Figure 83. PROGRAM_MEM_06 Register
7
6
5
4
3
2
1
0
cmd03_msb
R/W-0h
Table 72. PROGRAM_MEM_06 Register Field Descriptions
Bit
7–0
Field
cmd03_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.58 PROGRAM_MEM_07 Register (Address = 57h) [reset = 0h]
PROGRAM_MEM_07 is shown in Figure 84 and described in Table 73.
Return to Summary Table.
Program Memory 07 Register
Figure 84. PROGRAM_MEM_07 Register
7
6
5
4
3
2
1
0
cmd03_lsb
R/W-0h
Table 73. PROGRAM_MEM_07 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd03_lsb
R/W
0h
Program memory data
8.6.1.59 PROGRAM_MEM_08 Register (Address = 58h) [reset = 0h]
PROGRAM_MEM_08 is shown in Figure 85 and described in Table 74.
Return to Summary Table.
Program Memory 08 Register
Figure 85. PROGRAM_MEM_08 Register
7
6
5
4
3
2
1
0
cmd04_msb
R/W-0h
Table 74. PROGRAM_MEM_08 Register Field Descriptions
Bit
7–0
Field
cmd04_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.60 PROGRAM_MEM_09 Register (Address = 59h) [reset = 0h]
PROGRAM_MEM_09 is shown in Figure 86 and described in Table 75.
Return to Summary Table.
Program Memory 09 Register
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Figure 86. PROGRAM_MEM_09 Register
7
6
5
4
3
2
1
0
cmd04_lsb
R/W-0h
Table 75. PROGRAM_MEM_09 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd04_lsb
R/W
0h
Program memory data
8.6.1.61 PROGRAM_MEM_10 Register (Address = 5Ah) [reset = 0h]
PROGRAM_MEM_10 is shown in Figure 87 and described in Table 76.
Return to Summary Table.
Program Memory 10 Register
Figure 87. PROGRAM_MEM_10 Register
7
6
5
4
3
2
1
0
0
0
cmd05_msb
R/W-0h
Table 76. PROGRAM_MEM_10 Register Field Descriptions
Bit
7–0
Field
cmd05_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.62 PROGRAM_MEM_11 Register (Address = 5Bh) [reset = 0h]
PROGRAM_MEM_11 is shown in Figure 88 and described in Table 77.
Return to Summary Table.
Program Memory 11 Register
Figure 88. PROGRAM_MEM_11 Register
7
6
5
4
3
2
1
cmd05_lsb
R/W-0h
Table 77. PROGRAM_MEM_11 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd05_lsb
R/W
0h
Program memory data
8.6.1.63 PROGRAM_MEM_12 Register (Address = 5Ch) [reset = 0h]
PROGRAM_MEM_12 is shown in Figure 89 and described in Table 78.
Return to Summary Table.
Program Memory 12 Register
Figure 89. PROGRAM_MEM_12 Register
7
6
5
4
3
2
1
cmd06_msb
R/W-0h
66
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Table 78. PROGRAM_MEM_12 Register Field Descriptions
Bit
Field
Type
Reset
Description
Program memory data
7–0
cmd06_msb
R/W
0h
8.6.1.64 PROGRAM_MEM_13 Register (Address = 5Dh) [reset = 0h]
PROGRAM_MEM_13 is shown in Figure 90 and described in Table 79.
Return to Summary Table.
Program Memory 13 Register
Figure 90. PROGRAM_MEM_13 Register
7
6
5
4
3
2
1
1
1
0
0
0
cmd06_lsb
R/W-0h
Table 79. PROGRAM_MEM_13 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd06_lsb
R/W
0h
Program memory data
8.6.1.65 PROGRAM_MEM_14 Register (Address = 5Eh) [reset = 0h]
PROGRAM_MEM_14 is shown in Figure 91 and described in Table 80.
Return to Summary Table.
Program Memory 14 Register
Figure 91. PROGRAM_MEM_14 Register
7
6
5
4
3
2
cmd07_msb
R/W-0h
Table 80. PROGRAM_MEM_14 Register Field Descriptions
Bit
7–0
Field
cmd07_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.66 PROGRAM_MEM_15 Register (Address = 5Fh) [reset = 0h]
PROGRAM_MEM_15 is shown in Figure 92 and described in Table 81.
Return to Summary Table.
Program Memory 15 Register
Figure 92. PROGRAM_MEM_15 Register
7
6
5
4
3
2
cmd07_lsb
R/W-0h
Table 81. PROGRAM_MEM_15 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd07_lsb
R/W
0h
Program memory data
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8.6.1.67 PROGRAM_MEM_16 Register (Address = 60h) [reset = 0h]
PROGRAM_MEM_16 is shown in Figure 93 and described in Table 82.
Return to Summary Table.
Program Memory 16 Register
Figure 93. PROGRAM_MEM_16 Register
7
6
5
4
3
2
1
0
cmd08_msb
R/W-0h
Table 82. PROGRAM_MEM_16 Register Field Descriptions
Bit
7–0
Field
cmd08_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.68 PROGRAM_MEM_17 Register (Address = 61h) [reset = 0h]
PROGRAM_MEM_17 is shown in Figure 94 and described in Table 83.
Return to Summary Table.
Program Memory 17 Register
Figure 94. PROGRAM_MEM_17 Register
7
6
5
4
3
2
1
0
cmd08_lsb
R/W-0h
Table 83. PROGRAM_MEM_17 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd08_lsb
R/W
0h
Program memory data
8.6.1.69 PROGRAM_MEM_18 Register (Address = 62h) [reset = 0h]
PROGRAM_MEM_18 is shown in Figure 95 and described in Table 84.
Return to Summary Table.
Program Memory 18 Register
Figure 95. PROGRAM_MEM_18 Register
7
6
5
4
3
2
1
0
cmd09_msb
R/W-0h
Table 84. PROGRAM_MEM_18 Register Field Descriptions
Bit
7–0
Field
cmd09_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.70 PROGRAM_MEM_19 Register (Address = 63h) [reset = 0h]
PROGRAM_MEM_19 is shown in Figure 96 and described in Table 85.
Return to Summary Table.
Program Memory 19 Register
68
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Figure 96. PROGRAM_MEM_19 Register
7
6
5
4
3
2
1
0
cmd09_lsb
R/W-0h
Table 85. PROGRAM_MEM_19 Register Field Descriptions
Bit
Field
Type
Reset
Description
7–0
cmd09_lsb
R/W
0h
Program memory data
8.6.1.71 PROGRAM_MEM_20 Register (Address = 64h) [reset = 0h]
PROGRAM_MEM_20 is shown in Figure 97 and described in Table 86.
Return to Summary Table.
Program Memory 20 Register
Figure 97. PROGRAM_MEM_20 Register
7
6
5
4
3
2
1
0
cmd10_msb
R/W-0h
Table 86. PROGRAM_MEM_20 Register Field Descriptions
Bit
7–0
Field
cmd10_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.72 PROGRAM_MEM_21 Register (Address = 65h) [reset = 0h]
PROGRAM_MEM_21 is shown in Figure 98 and described in Table 87.
Return to Summary Table.
Program Memory 21 Register
Figure 98. PROGRAM_MEM_21 Register
7
6
5
4
3
2
1
0
cmd10_lsb
R/W-0h
Table 87. PROGRAM_MEM_21 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd10_lsb
R/W
0h
Program memory data
8.6.1.73 PROGRAM_MEM_22 Register (Address = 66h) [reset = 0h]
PROGRAM_MEM_22 is shown in Figure 99 and described in Table 88.
Return to Summary Table.
Program Memory 22 Register
Figure 99. PROGRAM_MEM_22 Register
7
6
5
4
3
2
1
0
cmd11_msb
R/W-0h
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Table 88. PROGRAM_MEM_22 Register Field Descriptions
Bit
Field
Type
Reset
Description
7–0
cmd11_msb
R/W
0h
Program memory data
8.6.1.74 PROGRAM_MEM_23 Register (Address = 67h) [reset = 0h]
PROGRAM_MEM_23 is shown in Figure 100 and described in Table 89.
Return to Summary Table.
Program Memory 23 Register
Figure 100. PROGRAM_MEM_23 Register
7
6
5
4
3
2
1
1
1
0
cmd11_lsb
R/W-0h
Table 89. PROGRAM_MEM_23 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd11_lsb
R/W
0h
Program memory data
8.6.1.75 PROGRAM_MEM_24 Register (Address = 68h) [reset = 0h]
PROGRAM_MEM_24 is shown in Figure 101 and described in Table 90.
Return to Summary Table.
Program Memory 24 Register
Figure 101. PROGRAM_MEM_24 Register
7
6
5
4
3
2
0
cmd12_msb
R/W-0h
Table 90. PROGRAM_MEM_24 Register Field Descriptions
Bit
7–0
Field
cmd12_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.76 PROGRAM_MEM_25 Register (Address = 69h) [reset = 0h]
PROGRAM_MEM_25 is shown in Figure 102 and described in Table 91.
Return to Summary Table.
Program Memory 25 Register
Figure 102. PROGRAM_MEM_25 Register
7
6
5
4
3
2
0
cmd12_lsb
R/W-0h
Table 91. PROGRAM_MEM_25 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd12_lsb
R/W
0h
Program memory data
70
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8.6.1.77 PROGRAM_MEM_26 Register (Address = 6Ah) [reset = 0h]
PROGRAM_MEM_26 is shown in Figure 103 and described in Table 92.
Return to Summary Table.
Program Memory 26 Register
Figure 103. PROGRAM_MEM_26 Register
7
6
5
4
3
2
1
0
cmd13_msb
R/W-0h
Table 92. PROGRAM_MEM_26 Register Field Descriptions
Bit
7–0
Field
cmd13_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.78 PROGRAM_MEM_27 Register (Address = 6Bh) [reset = 0h]
PROGRAM_MEM_27 is shown in Figure 104 and described in Table 93.
Return to Summary Table.
Program Memory 27 Register
Figure 104. PROGRAM_MEM_27 Register
7
6
5
4
3
2
1
0
cmd13_lsb
R/W-0h
Table 93. PROGRAM_MEM_27 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd13_lsb
R/W
0h
Program memory data
8.6.1.79 PROGRAM_MEM_28 Register (Address = 6Ch) [reset = 0h]
PROGRAM_MEM_28 is shown in Figure 105 and described in Table 94.
Return to Summary Table.
Program Memory 28 Register
Figure 105. PROGRAM_MEM_28 Register
7
6
5
4
3
2
1
0
cmd14_msb
R/W-0h
Table 94. PROGRAM_MEM_28 Register Field Descriptions
Bit
7–0
Field
cmd14_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.80 PROGRAM_MEM_29 Register (Address = 6Dh) [reset = 0h]
PROGRAM_MEM_29 is shown in Figure 106 and described in Table 95.
Return to Summary Table.
Program Memory 29 Register
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Figure 106. PROGRAM_MEM_29 Register
7
6
5
4
3
2
1
0
cmd14_lsb
R/W-0h
Table 95. PROGRAM_MEM_29 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd14_lsb
R/W
0h
Program memory data
8.6.1.81 PROGRAM_MEM_30 Register (Address = 6Eh) [reset = 0h]
PROGRAM_MEM_30 is shown in Figure 107 and described in Table 96.
Return to Summary Table.
Program Memory 30 Register
Figure 107. PROGRAM_MEM_30 Register
7
6
5
4
3
2
1
0
0
0
cmd15_msb
R/W-0h
Table 96. PROGRAM_MEM_30 Register Field Descriptions
Bit
7–0
Field
cmd15_msb
Type
Reset
Description
R/W
0h
Program memory data
8.6.1.82 PROGRAM_MEM_31 Register (Address = 6Fh) [reset = 0h]
PROGRAM_MEM_31 is shown in Figure 108 and described in Table 97.
Return to Summary Table.
Program Memory 31 Register
Figure 108. PROGRAM_MEM_31 Register
7
6
5
4
3
2
1
cmd15_lsb
R/W-0h
Table 97. PROGRAM_MEM_31 Register Field Descriptions
Bit
7–0
Field
Type
Reset
Description
cmd15_lsb
R/W
0h
Program memory data
8.6.1.83 ENGINE1_MAPPING1 Register (Address = 70h) [reset = 0h]
ENGINE1_MAPPING1 is shown in Figure 109 and described in Table 98.
Return to Summary Table.
Engine1 Mapping1 Register
Figure 109. ENGINE1_MAPPING1 Register
7
6
5
4
3
2
1
eng1_map_ma eng1_map_led
ster_fader1
RESERVED
R-0h
8
R-0h
R-0h
72
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Table 98. ENGINE1_MAPPING1 Register Field Descriptions
Bit
7–2
1
Field
Type
R
Reset
0h
Description
RESERVED
eng1_map_master_fader1
R
0h
0 = Program execution engine 1 master fader disabled.
1 = Program execution engine 1 master fader enabled.
0
eng1_map_led8
R
0h
0 = LED8 is not mapped to the program execution engine 1.
1 = LED8 is mapped to the program execution engine 1.
8.6.1.84 ENGINE1_MAPPING2 Register (Address = 71h) [reset = 0h]
ENGINE1_MAPPING2 is shown in Figure 110 and described in Table 99.
Return to Summary Table.
Engine1 Mapping2 Register
Figure 110. ENGINE1_MAPPING2 Register
7
6
5
4
3
2
1
0
eng1_map_led eng1_map_led eng1_map_led eng1_map_led eng1_map_led eng1_map_led eng1_map_led eng1_map_led
7
6
5
4
3
2
1
0
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
Table 99. ENGINE1_MAPPING2 Register Field Descriptions
Bit
Field
Type
Reset
Description
7
6
5
4
3
2
1
0
eng1_map_led7
eng1_map_led6
eng1_map_led5
eng1_map_led4
eng1_map_led3
eng1_map_led2
eng1_map_led1
eng1_map_led0
R
0h
0 = LED7 is not mapped to program execution engine 1.
1 = LED7 is mapped to program execution engine 1.
R
R
R
R
R
R
R
0h
0h
0h
0h
0h
0h
0h
0 = LED6 is not mapped to program execution engine 1.
1 = LED6 is mapped to program execution engine 1.
0 = LED5 is not mapped to program execution engine 1.
1 = LED5 is mapped to program execution engine 1.
0 = LED4 is not mapped to program execution engine 1.
1 = LED4 is mapped to program execution engine 1.
0 = LED3 is not mapped to program execution engine 1.
1 = LED3 is mapped to program execution engine 1.
0 = LED2 is not mapped to program execution engine 1.
1 = LED2 is mapped to program execution engine 1.
0 = LED1 is not mapped to program execution engine 1.
1 = LED1 is mapped to program execution engine 1.
0 = LED0 is not mapped to program execution engine 1.
1 = LED0 is mapped to program execution engine 1.
8.6.1.85 ENGINE2_MAPPING1 Register (Address = 72h) [reset = 0h]
ENGINE2_MAPPING1 is shown in Figure 111 and described in Table 100.
Return to Summary Table.
Engine2 Mapping1 Register
Figure 111. ENGINE2_MAPPING1 Register
7
6
5
4
3
2
1
0
RESERVED
R-0h
eng2_map_ma eng2_map_led
ster_fader2
8
R-0h
R-0h
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Table 100. ENGINE2_MAPPING1 Register Field Descriptions
Bit
7–2
1
Field
Type
R
Reset
0h
Description
RESERVED
eng2_map_master_fader2
R
0h
0 = Program execution engine 2 master fader disabled.
1 = Program execution engine 2 master fader enabled.
0
eng2_map_led8
R
0h
0 = LED8 is not mapped to the program execution engine 2.
1 = LED8 is mapped to the program execution engine 2.
8.6.1.86 ENGINE2_MAPPING2 Register (Address = 73h) [reset = 0h]
ENGINE2_MAPPING2 is shown in Figure 112 and described in Table 101.
Return to Summary Table.
Engine2 Mapping2 Register
Figure 112. ENGINE2_MAPPING2 Register
7
6
5
4
3
2
1
0
eng2_map_led eng2_map_led eng2_map_led eng2_map_led eng2_map_led eng2_map_led eng2_map_led eng2_map_led
7
6
5
4
3
2
1
0
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
Table 101. ENGINE2_MAPPING2 Register Field Descriptions
Bit
Field
Type
Reset
Description
7
6
5
4
3
2
1
0
eng2_map_led7
eng2_map_led6
eng2_map_led5
eng2_map_led4
eng2_map_led3
eng2_map_led2
eng2_map_led1
eng2_map_led0
R
0h
0 = LED7 is not mapped to program execution engine 2.
1 = LED7 is mapped to program execution engine 2.
R
R
R
R
R
R
R
0h
0h
0h
0h
0h
0h
0h
0 = LED6 is not mapped to program execution engine 2.
1 = LED6 is mapped to program execution engine 2.
0 = LED5 is not mapped to program execution engine 2.
1 = LED5 is mapped to program execution engine 2.
0 = LED4 is not mapped to program execution engine 2.
1 = LED4 is mapped to program execution engine 2.
0 = LED3 is not mapped to program execution engine 2.
1 = LED3 is mapped to program execution engine 2.
0 = LED2 is not mapped to program execution engine 2.
1 = LED2 is mapped to program execution engine 2.
0 = LED1 is not mapped to program execution engine 2.
1 = LED1 is mapped to program execution engine 2.
0 = LED0 is not mapped to program execution engine 2.
1 = LED0 is mapped to program execution engine 2.
8.6.1.87 ENGINE3_MAPPING1 Register (Address = 74h) [reset = 0h]
ENGINE3_MAPPING1 is shown in Figure 113 and described in Table 102.
Return to Summary Table.
Engine3 Mapping1 Register
Figure 113. ENGINE3_MAPPING1 Register
7
6
5
4
3
2
1
0
RESERVED
R-0h
eng3_map_ma eng3_map_led
ster_fader3
8
R-0h
R-0h
74
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Table 102. ENGINE3_MAPPING1 Register Field Descriptions
Bit
7–2
1
Field
Type
R
Reset
0h
Description
RESERVED
eng3_map_master_fader3
R
0h
0 = Program execution engine 3 master fader disabled.
1 = Program execution engine 3 master fader enabled.
0
eng3_map_led8
R
0h
0 = LED8 is not mapped to the program execution engine 3.
1 = LED8 is mapped to the program execution engine 3.
8.6.1.88 ENGINE3_MAPPING2 Register (Address = 75h) [reset = 0h]
ENGINE3_MAPPING2 is shown in Figure 114 and described in Table 103.
Return to Summary Table.
Engine3 Mapping2 Register
Figure 114. ENGINE3_MAPPING2 Register
7
6
5
4
3
2
1
0
eng3_map_led eng3_map_led eng3_map_led eng3_map_led eng3_map_led eng3_map_led eng3_map_led eng3_map_led
7
6
5
4
3
2
1
0
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
R-0h
Table 103. ENGINE3_MAPPING2 Register Field Descriptions
Bit
Field
Type
Reset
Description
7
6
5
4
3
2
1
0
eng3_map_led7
eng3_map_led6
eng3_map_led5
eng3_map_led4
eng3_map_led3
eng3_map_led2
eng3_map_led1
eng3_map_led0
R
0h
0 = LED7 is not mapped to program execution engine 3.
1 = LED7 is mapped to program execution engine 3.
R
R
R
R
R
R
R
0h
0h
0h
0h
0h
0h
0h
0 = LED6 is not mapped to program execution engine 3.
1 = LED6 is mapped to program execution engine 3.
0 = LED5 is not mapped to program execution engine 3.
1 = LED5 is mapped to program execution engine 3.
0 = LED4 is not mapped to program execution engine 3.
1 = LED4 is mapped to program execution engine 3.
0 = LED3 is not mapped to program execution engine 3.
1 = LED3 is mapped to program execution engine 3.
0 = LED2 is not mapped to program execution engine 3.
1 = LED2 is mapped to program execution engine 3.
0 = LED1 is not mapped to program execution engine 3.
1 = LED1 is mapped to program execution engine 3.
0 = LED0 is not mapped to program execution engine 3.
1 = LED0 is mapped to program execution engine 3.
8.6.1.89 PWM_CONFIG Register (Address = 80h) [reset = 4h]
PWM_CONFIG is shown in Figure 115 and described in Table 104.
Return to Summary Table.
PWM Configuration Register
Figure 115. PWM_CONFIG Register
7
6
5
4
3
2
1
0
pwm_min_pulse_width
RESERVED
R/W-0h
pwm_input_edg
e_sel
pwm_input_hysteresis
R/W-0h
R/W-0h
R/W-4h
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Table 104. PWM_CONFIG Register Field Descriptions
Bit
Field
Type
Reset
Description
7–6
pwm_min_pulse_width
R/W
0h
Minimum output PWM pulse duration allowed. Applies to all PWM
outputs.
00 = Minimum PWM pulse duration = 1 clk period (100 ns, default)
01 = Minimum PWM pulse duration = 2 clk periods (200 ns)
10 = Minimum PWM pulse duration = 3 clk periods (300 ns)
11 = Minimum PWM pulse duration = 4 clk periods (400 ns)
5–4
3
RESERVED
R/W
R/W
0h
0h
pwm_input_edge_sel
PWM input period measurement select.
0h = PWM period is measured from rising edge to rising edge.
(default)
1h = PWM period is measured from falling edge to falling edge.
2–0
pwm_input_hysteresis
R/W
4h
PWM input hysteresis select
0h = No hysteresis
1h = 1 LSB
2h = 2 LSBs
3h = 3 LSBs
4h = 4 LSBs (default)
5h = 5 LSBs
6h = 6 LSBs
7h = 7 LSBs
8.6.1.90 LED_FAULT1 Register (Address = 81h) [reset = 0h]
LED_FAULT1 is shown in Figure 116 and described in Table 105.
Return to Summary Table.
LED Fault 1 Register
Figure 116. LED_FAULT1 Register
7
6
5
4
3
2
1
0
RESERVED
R-0h
led_fault8
R-0h
Table 105. LED_FAULT1 Register Field Descriptions
Bit
Field
Type
R
Reset
0h
Description
7–1
0
RESERVED
led_fault8
R
0h
LED fault status for LED8
8.6.1.91 LED_FAULT2 Register (Address = 82h) [reset = 0h]
LED_FAULT2 is shown in Figure 117 and described in Table 106.
Return to Summary Table.
LED Fault 2 Register
Figure 117. LED_FAULT2 Register
7
6
5
4
3
2
1
0
led_fault_7
R-0h
led_fault_6
R-0h
led_fault_5
R-0h
led_fault_4
R-0h
led_fault_3
R-0h
led_fault_2
R-0h
led_fault_1
R-0h
led_fault_0
R-0h
76
Copyright © 2017, Texas Instruments Incorporated
LP5569
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ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
Table 106. LED_FAULT2 Register Field Descriptions
Bit
Field
Type
Reset
Description
7
led_fault_7
R
0h
LED fault status for LED7
LED fault status for LED6
LED fault status for LED5
LED fault status for LED4
LED fault status for LED3
LED fault status for LED2
LED fault status for LED1
LED fault status for LED0
6
5
4
3
2
1
0
led_fault_6
led_fault_5
led_fault_4
led_fault_3
led_fault_2
led_fault_1
led_fault_0
R
R
R
R
R
R
R
0h
0h
0h
0h
0h
0h
0h
8.6.1.92 GENERAL_FAULT Register (Address = 83h) [reset = 4h]
GENERAL_FAULT is shown in Figure 118 and described in Table 107.
Return to Summary Table.
General Fault Register
Figure 118. GENERAL_FAULT Register
7
6
5
4
3
2
1
0
RESERVED
cp_cap_missin
g
vdd_uvlo
tsd
R-0h
R-1h
R-0h
R-0h
Table 107. GENERAL_FAULT Register Field Descriptions
Bit
Field
Type
R
Reset
0h
Description
7–3
2
RESERVED
cp_cap_missing
R
1h
0 = CP capacitor detected
1 = CP capacitor missing or CP disabled
1
0
vdd_uvlo
tsd
R
R
0h
0h
0 = No UVLO fault
1 = UVLO fault
0 = No TSD fault
1 = TSD fault
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9 Application and Implementation
注
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
9.1 Application Information
The LP5569 device is designed as an autonomous lighting controller for handheld devices. In these devices,
extremely small form factor is needed; therefore, the LP5569 device is designed to require only four small
capacitors: input and output, as well as flying capacitor 1 and flying capacitor 2 for the charge pump. If the
system has other LED input voltages available, and the charge pump is not needed in the application, the
charge-pump capacitors can be omitted, thus reducing the solution even further. The device can drive RGB
LEDs or discrete LEDs of any color if desired.
9.2 Typical Applications
9.2.1 Single LP5569 Application
图 119 shows an example of a typical application that uses a charge pump to get high-enough voltage to drive
green and blue LEDs. Red LEDs are powered from VVIN for reduced power consumption. The device, with a
voltage range of 2.5 V to 4.5 V, is powered from three AA batteries, typically 3.6 V with 1.2-V cell voltage. Design
Requirements shows related design parameters for this example. In this example, input voltage with AA batteries
is typically over 3.6 V (cell voltage >1.2 V) for half of the battery lifetime. During this time the charge pump
operates in 1× mode, as the input voltage is enough for the green and blue LEDs. As the battery voltage
continues to decrease, the LP5569 device detects that the LED headroom voltage is too low and automatically
configures the charge pump to the 1.5× mode. In 1.5× mode, the LEDs can be powered with VIN down to 2.5 V,
where the batteries are almost empty.
78
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LP5569
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ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
Typical Applications (接下页)
CFLY1
1 µF
CFLY2
C1–
C1+
C2–
C2
VIN = 2.5 V to 4.5 V, 3.6V typ
VIN
VOUT
PGND
COUT
1 µF
CIN
1 µF
3 x AA
DC/DC
V1P8
LED0
LED1
LED2
VIN
SCL
SDA
LED3
LED4
µC
EN/PWM
CLK
LED5
LED6
LED7
LED8
GPIO/TRIG/INT
ADDR
AGND
Copyright © 2017, Texas Instruments Incorporated
图 119. LP5569 Typical Application
9.2.1.1 Design Requirements
DESIGN PARAMETER
Input voltage range
LED VF (maximum)
LED current
EXAMPLE VALUE
2.5 V to 5.5 V
3.2 V
25.5 mA maximum
CIN = 1 µF
Input capacitor
Output capacitor
COUT = 1 µF
Charge pump flying capacitors
Charge-pump mode
CFLY1 = CFLY2 = 1 µF
1.5× or automatic
9.2.1.2 Detailed Design Procedure
The LP5569 device requires four external capacitors for proper operation. TI recommends surface-mount multi-
layer ceramic capacitors. Tantalum and aluminum capacitors are not recommended because of their high ESR.
Multi-layer ceramic capacitors must always be used for the flying capacitors (CFLY1 and CFLY2). Ceramic
capacitors with an X7R or X5R temperature characteristic are preferred for use with the LP5569 device. These
capacitors have tight capacitance tolerance (as good as ±10%) and hold their value over temperature (X7R:
±15% over −55°C to 125°C; X5R: ±15% over −55°C to 85°C).
It is necessary to have at least 0.24 μF of effective capacitance for each of the flying capacitors under all
operating conditions to ensure proper operation. The output capacitor COUT directly affects the magnitude of the
output ripple voltage. In general, the higher the value of COUT, the lower the output-ripple magnitude. For proper
operation TI recommends having at least 0.5 μF of effective capacitance for CIN and COUT under all operating
conditions. The voltage rating of all four capacitors must be 6.3 V (minimum), with 10 V preferred.
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www.ti.com.cn
表 108 lists suitable external components from some leading ceramic capacitor manufacturers.
表 108. Suitable External Components
MODEL
TYPE
VENDOR
TDK
VOLTAGE RATING (V)
PACKAGE SIZE
C1005X5R1A105K
LMK105BJ105KV-F
ECJ0EB1A105M
Ceramic X5R
Ceramic X5R
Ceramic X5R
10
10
10
0402
0402
0402
Taiyo Yuden
Panasonic
9.2.1.3 Application Curves
图 121. PWM Dither Waveform
图 120. Start-Up Waveform
9.2.2 Using Multiple LP5569 Devices
The LP5569 device enables up to eight parallel devices together, which can drive up to 24 RGB LEDs or 72
single LEDs. 图 122 shows the connections for two LP5569 devices for six RGB LEDs. Note that the LED6,
LED7, and LED8 outputs are used for the red LEDs. The SCL and SDA lines must each have a pullup resistor
placed somewhere on the line (R2 and R3; the pullup resistors are normally located on the bus master). In
typical applications, values of 1.8 kΩ to 4.7 kΩ are used, depending on the bus capacitance, I/O voltage, and the
desired communication speed. GPIO/TRIG/INT is open drain, which requires a pullup resistor. The typical value
for R1 is from 120 kΩ to 180 kΩ for two LP5569 devices.
80
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LP5569
www.ti.com.cn
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
C1
C2
1 µF
1 µF
C2+ C2Å
C1Å
C1+
V1P8
VIN
1.8 V
VIN
VOUT
2.5 V to 5.5 V
CIN1
VIN
COUT1
1 µF
PGND
1 µF
R1 R2 R3
LED0
LED1
LED2
SCL
SDA
MCU
GPIO/TRIG/INT
EN/PWM
LED3
LED4
LED5
CLK
ADDR
AGND
LED6
LED7
LED8
C3
1 µF
C4
1 µF
VIN 1.8 V
C2+ C2Å
C1Å
C1+
V1P8
VOUT
COUT2
1 µF
VIN
CIN2
1 µF
PGND
LED0
LED1
LED2
SCL
SDA
GPIO/TRIG/INT
EN/PWM
LED3
LED4
LED5
CLK
ADDR
AGND
LED6
LED7
LED8
Copyright © 2016, Texas Instruments Incorporated
图 122. Dual LP5569 Application Example
版权 © 2017, Texas Instruments Incorporated
81
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www.ti.com.cn
9.2.2.1 Design Requirements
DESIGN PARAMETER
Input voltage range
LED VF (maximum)
LED current
EXAMPLE VALUE
2.5 V to 5.5 V
3.2 V
25.5 mA maximum
CIN = 1 µF
Input capacitor
Output capacitor
COUT= 1 µF
Charge pump flying capacitors
Charge-pump mode
CFLY1 = CFLY2 = 1 µF
1.5× or automatic
9.2.2.2 Detailed Design Procedure
External component selection follows the earlier example (see Detailed Design Procedure).
9.2.2.3 Application Curves
图 123. Line Transient of the Riasing Edge in Charge-
图 124. Line Transient of the Falling Edge in Charge-Pump
Pump Auto Mode
Auto Mode
10 Power Supply Recommendations
The device is designed to operate from a VVIN input-voltage supply range between 2.5 V and 5.5 V. This input
supply must be well-regulated and able to withstand maximum input current and maintain stable voltage without
voltage drop even in a load-transition condition (start-up or rapid brightness change). The resistance of the input
supply rail must be low enough that the input-current transient does not cause a drop below 2.5-V in the LP5569
VVIN supply voltage.
82
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LP5569
www.ti.com.cn
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
11 Layout
11.1 Layout Guidelines
The charge pump basically has three areas of concern regarding component placement:
•
•
•
The flying capacitors
The output capacitor
The input capacitor
11.1.1 Flying Capacitor Placement
The charge pump flying capacitors must quickly charge up and then supply current to the output every switching
cycle. Because the charge-pump switching frequency is 1.25 MHz, the capacitor must be a low-inductance and
low-resistance ceramic. Additionally, there must be a low-inductive connection between the flying capacitors and
LP5569 pins C1P, C2P, C1M, and C2M.
11.1.2 Output Capacitor Placement
The charge-pump output capacitor is charged by the flying capacitor every switching cycle (1.25 MHz). This fast
switching action requires that a low-inductance and low-resistance capacitor (ceramic) be used and that the
output capacitor be connected to the LP5569 VOUT pin with a low-inductance connection. This is done by
placing the output capacitor as close as possible to the VOUT and PGND pins of the LP5569 device, with
connections on the same layer to avoid vias.
11.1.3 Input Capacitor Placement
The charge pump input capacitor is discharged by the flying capacitor every switching cycle (0.8 µs). This fast
switching action requires that a low-inductance and low-resistance capacitor (ceramic) be used and that the input
capacitor be connected to the LP5569 VIN pin with a low-inductive connection. This is done by placing the output
capacitor as close as possible to the VOUT and AGND pins of the LP5569 device, with connections on the same
layer to avoid vias.
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11.2 Layout Example
Ço [95s
ëias to Db5 plane
Lnput ëoltage
LED7
LED0
ADDR
PGND
VOUT
C2Å
LED8
V1P8
SCL
SDA
INT
C1Å
/ontrol signals
Copyright © 2017, Texas Instruments Incorporated
图 125. LP5569 Layout Example
84
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LP5569
www.ti.com.cn
ZHCSGU2A –JULY 2017–REVISED SEPTEMBER 2017
12 器件和文档支持
12.1 器件支持
12.1.1 Third-Party Products Disclaimer
TI'S PUBLICATION OF INFORMATION REGARDING THIRD-PARTY PRODUCTS OR SERVICES DOES NOT
CONSTITUTE AN ENDORSEMENT REGARDING THE SUITABILITY OF SUCH PRODUCTS OR SERVICES
OR A WARRANTY, REPRESENTATION OR ENDORSEMENT OF SUCH PRODUCTS OR SERVICES, EITHER
ALONE OR IN COMBINATION WITH ANY TI PRODUCT OR SERVICE.
12.2 接收文档更新通知
要接收文档更新通知,请导航至 TI.com 上的器件产品文件夹。单击右上角的通知我 进行注册,即可每周接收产品
信息更改摘要。有关更改的详细信息,请查看任何已修订文档中包含的修订历史记录。
12.3 社区资源
下列链接提供到 TI 社区资源的连接。链接的内容由各个分销商“按照原样”提供。这些内容并不构成 TI 技术规范,
并且不一定反映 TI 的观点;请参阅 TI 的 《使用条款》。
TI E2E™ 在线社区 TI 的工程师对工程师 (E2E) 社区。此社区的创建目的在于促进工程师之间的协作。在
e2e.ti.com 中,您可以咨询问题、分享知识、拓展思路并与同行工程师一道帮助解决问题。
设计支持
TI 参考设计支持 可帮助您快速查找有帮助的 E2E 论坛、设计支持工具以及技术支持的联系信息。
12.4 商标
E2E is a trademark of Texas Instruments.
蓝牙 is a registered trademark of Bluetooth SIG, Inc..
All other trademarks are the property of their respective owners.
12.5 静电放电警告
这些装置包含有限的内置 ESD 保护。 存储或装卸时,应将导线一起截短或将装置放置于导电泡棉中,以防止 MOS 门极遭受静电损
伤。
12.6 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
13 机械、封装和可订购信息
以下页面包含机械、封装和可订购信息。这些信息是针对指定器件提供的最新数据。本数据随时可能发生变更并且
不对本文档进行修订,恕不另行通知。要获得这份数据表的浏览器版本,请查阅左侧的导航窗格。
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PACKAGE OPTION ADDENDUM
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28-Sep-2021
PACKAGING INFORMATION
Orderable Device
Status Package Type Package Pins Package
Eco Plan
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
Samples
Drawing
Qty
(1)
(2)
(3)
(4/5)
(6)
LP5569ARTWR
LP5569RTWR
ACTIVE
ACTIVE
WQFN
WQFN
RTW
RTW
24
24
3000 RoHS & Green
3000 RoHS & Green
NIPDAU
Level-1-260C-UNLIM
Level-1-260C-UNLIM
-40 to 85
-40 to 85
5569A
5569
NIPDAU
(1) The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based
flame retardants must also meet the <=1000ppm threshold requirement.
(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two
lines if the finish value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
PACKAGE OPTION ADDENDUM
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28-Sep-2021
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
30-Apr-2018
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
B0
K0
P1
W
Pin1
Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant
(mm) W1 (mm)
LP5569ARTWR
LP5569RTWR
WQFN
WQFN
RTW
RTW
24
24
3000
3000
330.0
330.0
12.4
12.4
4.25
4.25
4.25
4.25
1.15
1.15
8.0
8.0
12.0
12.0
Q2
Q2
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
30-Apr-2018
*All dimensions are nominal
Device
Package Type Package Drawing Pins
SPQ
Length (mm) Width (mm) Height (mm)
LP5569ARTWR
LP5569RTWR
WQFN
WQFN
RTW
RTW
24
24
3000
3000
367.0
367.0
367.0
367.0
35.0
35.0
Pack Materials-Page 2
PACKAGE OUTLINE
WQFN - 0.8 mm max height
PLASTIC QUAD FLATPACK-NO LEAD
RTW0024B
4.15
3.85
A
B
4.15
3.85
PIN 1 INDEX AREA
C
0.8 MAX
SEATING PLANE
0.08 C
0.05
0.00
(0.2) TYP
2X 2.5
EXPOSED
THERMAL PAD
12
7
20X 0.5
6
13
25
SYMM
2X
2.5
2.45±0.1
1
18
0.3
24X
0.18
19
0.5
24
PIN 1 ID
(OPTIONAL)
0.1
C A B
SYMM
0.05
C
24X
0.3
4219135/B 11/2016
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
www.ti.com
EXAMPLE BOARD LAYOUT
WQFN - 0.8 mm max height
PLASTIC QUAD FLATPACK-NO LEAD
RTW0024B
(
2.45)
SYMM
24
19
24X (0.6)
1
18
24X (0.24)
(0.97)
25
SYMM
(3.8)
20X (0.5)
(R0.05)
TYP
13
6
(Ø0.2) TYP
VIA
7
12
(0.97)
(3.8)
LAND PATTERN EXAMPLE
SCALE: 20X
0.07 MAX
ALL AROUND
0.07 MIN
ALL AROUND
SOLDER MASK
OPENING
METAL
SOLDER MASK
OPENING
METAL UNDER
SOLDER MASK
NON SOLDER MASK
DEFINED
SOLDER MASK
DEFINED
(PREFERRED)
SOLDER MASK DETAILS
4219135/B 11/2016
NOTES: (continued)
3. For more information, see Texas Instruments literature number SLUA271 (www.ti.com/lit/slua271).
www.ti.com
EXAMPLE STENCIL DESIGN
WQFN - 0.8 mm max height
PLASTIC QUAD FLATPACK-NO LEAD
RTW0024B
4X( 1.08)
(0.64) TYP
19
24
(R0.05) TYP
24X (0.6)
25
1
18
(0.64)
TYP
24X (0.24)
SYMM
(3.8)
20X (0.5)
13
6
7
12
METAL
TYP
SYMM
(3.8)
SOLDER PASTE EXAMPLE
BASED ON 0.125 mm THICK STENCIL
EXPOSED PAD 25:
78% PRINTED COVERAGE BY AREA UNDER PACKAGE
SCALE: 20X
4219135/B 11/2016
NOTES: (continued)
4. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
www.ti.com
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