C1608X7R1H152K [TI]

High-Integration, High-Efficiency Power Solution Using DC/DC Converters With DVFS; 高集成度，高效率电源解决方案采用DC / DC转换器，带有DVFS


型号：	C1608X7R1H152K
厂家：	TEXAS INSTRUMENTS
描述：	High-Integration, High-Efficiency Power Solution Using DC/DC Converters With DVFS 高集成度，高效率电源解决方案采用DC / DC转换器，带有DVFS 转换器
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Application Report

SLVA340A–June 2009–Revised May 2010

High-Integration, High-Efficiency Power Solution Using

DC/DC Converters With DVFS

Ambreesh Tripathi .......................................................................... PMP - DC/DC Low-Power Converters

ABSTRACT

This reference design helps those desiring to design-in the TMS320C6742, TMS320C6746,

TMS320C6748 and OMAP-L138. This design, employing sequenced power supplies, describes a system

with an input voltage of 5V, and uses a high-efficiency DC/DC Converter with integrated FETs and DVFS

for a small, simple system.

Sequenced power supply architectures are becoming commonplace in high-performance microprocessor

and digital signal processor (DSP) systems. To save power and increase processing speeds, processor

cores have small-geometry cells that require lower supply voltages than the system-bus voltages. Power

management in these systems requires special attention. This application note addresses these topics

and suggests solutions for output-voltage sequencing.

Contents

Introduction .................................................................................................................. 1

Power Requirements ....................................................................................................... 2

Features ...................................................................................................................... 3

List of Material ............................................................................................................... 5

List of Figures

PMP4977 Reference Design Schematic.................................................................................

Optional circuit for DVDD_A, DVDD_B and DVDD_C .................................................................

Shows Sequencing in Start-Up Waveform ..............................................................................

DCDC1: Efficiency vs Output Current....................................................................................

DCDC2: Efficiency vs Output Current....................................................................................

DCDC3: Efficiency vs Output Current....................................................................................

List of Tables

PMP4977 List of Material ..................................................................................................

Introduction

In dual-voltage architectures, coordinated management of power supplies is necessary to avoid potential

problems and ensure reliable performance. Power supply designers must consider the timing and voltage

differences between core and I/O voltage supplies during power-up and power-down operations.

Sequencing refers to the order, timing and differential in which the two voltage rails are powered up and

down. A system designed without proper sequencing may be at risk for two types of failures. The first of

these represents a threat to the long term reliability of the dual-voltage device, while the second is more

immediate, with the possibility of damaging interface circuits in the processor or system devices such as

memory, logic or data-converter ICs.

I²C is a trademark of Philips Electronics N.V. Corporation.

SLVA340A–June 2009–Revised May 2010

High-Integration, High-Efficiency Power Solution Using DC/DC Converters With

DVFS

Power Requirements

www.ti.com

Another potential problem with improper supply sequencing is bus contention. Bus contention is a

condition when the processor and another device both attempt to control a bi-directional bus during power

up. Bus contention may also affect I/O reliability. Power supply designers should check the requirements

regarding bus contention for individual devices.

The power-on sequencing for the OMAP-L138, TMS320C6742, TMS320C6746, and TMS320C6748 are

shown in the Power Requirements table below. There is no specific required voltage ramp rate for any of

the supplies as long as the 3.3V rail never exceeds the 1.8V rail by more than 2V.

Also, in order to reduce the power consumption of the processor core, the Dynamic Voltage and

Frequency Scaling (DVFS) is used in the reference design. DVFS is a power management technique used

while the system-on-chip (SoC) is actively processing. This technique matches the operating frequency of

the hardware to the performance requirement of the active application scenario. Whenever clock

frequencies are lowered, operating voltages are also lowered as well to achieve power savings. In the

reference design, the TPS65023 is used that can scale its output voltage. It supports all five DVFS voltage

values (0.95V, 1V, 1.2V, 1.27V, and 1.35V) defined for VDD_MPU.

Power Requirements

The power requirements are as specify in the table.

(1) (2)

VOLTAGE

(V)

Imax

(mA)

SEQUENCING

ORDER

TIMING

DELAY

PIN NAME

RTC_CVDD

CVDD⁽⁴⁾

TOLERANCE

I/O

1.2

1.0 / 1.1 / 1.2

1.2

–25%, +10%

–9.75%, +10%

–5%, +10%

1⁽³⁾

Core

I/O

600

200

RVDD, PLL0_VDDA,

PLL1_VDDA, SATA_VDD,

USB_CVDD, USB0_VDDA12

I/O

USB0_VDDA18, USB1_VDDA18,

DDR_DVDD18, SATA_VDDR,

DVDD18

1.8

180

±5%

I/O

USB0_VDDA33, USB1_VDDA33

3.3

50 / 90⁽⁵⁾

±5%

DVDD3318_A, DVDD3318_B,

DVDD3318_C

1.8 / 3.3

4 / 5

(1)

(2)

If 1.8-V LVCMOS is used, power rails up with the 1.8-V rails. If 3.3-V LVCMOS is used, power it up with the ANALOG33 rails

(VDDA33_USB0/1)

There is no specific required voltage ramp rate for any of the supplies LVCMOS33 (USB0_VDDA33, USB1_VDDA33) never

exceeds STATIC18 (USB0_VDDA18, USB1_VDDA18, DDR_DVDD18, SATA_VDDR, DVDD18) by more than 2 V.

If RTC is not used/maintained on a separate supply, it can be included in the STATIC12 (fixed 1.2 V) group.

If using CVDD at fixed 1.2 V, all 1.2-V rails may be combined.

If DVDD3318_A, B, and C are powered independently, maximum power for each rail will be 1/3 the above maximum power.

(3)

(4)

(5)

High-Integration, High-Efficiency Power Solution Using DC/DC Converters With

DVFS

SLVA340A–June 2009–Revised May 2010

www.ti.com

Features

The design uses the following high-efficiency DC/DC Converter with integrated FETs .

INPUT VOLTAGE

~5V

HIGH EFFICIENCY AND INTEGRATION

(w DVFS)

COMBINE RTC AND STATIC 1.2

Core 1.2 V at 600 mA

TPS65023

Static 1.2 V + VRTC at 251 mA

Static 1.8 V at 230 mA

Static 3.3 V at 115 mA

Here, VRTC is included in the STATIC12 (fixed 1.2 V) group.

TPS65023

•

1.5-A, 90% Efficient Step-Down Converter for Processor Core (VDCDC1)

2 × 200-mA General-Purpose LDO

1.2-A, Up to 95% Efficient Step-Down Converter for System Voltage (VDCDC2)

1-A, 92% Efficient Step-Down Converter for Memory Voltage (VDCDC3)

Dynamic Voltage Management for Processor Core

I²C™ Compatible Serial Interface

More information on the device can be found from the data sheets

TPS65023, http://focus.ti.com/lit/ds/symlink/tps65023.pdf

•

SLVA340A–June 2009–Revised May 2010

High-Integration, High-Efficiency Power Solution Using DC/DC Converters With

DVFS

Features

www.ti.com

Figure 1. PMP4977 Reference Design Schematic

High-Integration, High-Efficiency Power Solution Using DC/DC Converters With

DVFS

SLVA340A–June 2009–Revised May 2010

www.ti.com

List of Material

Proper sequencing is ensured in the design with the use of simple circuits involving the use of NPN

transistors as required. Core 1.2 V at 600 mA comes first ,which in turn is level-shifted to input voltage

using NPN transistors to enable the DCDC3_EN ; hence, static 1.2 V + VRTC at 251 mA comes up which

also enable the DCDC2_EN and sequentially static 1.8 V at 230 mA comes up. This 1.8-V output from

DCDC2 converter enable the LDO and hence at last static 3.3 V at 115 mA comes up.

(1) Use three such LDOs to power up DVDDA, DVDDB, and DVDDC. (It can either be 1.8 V or 3.3 V.)

(2) Rx = 0.499 MΩ, Ry = 1 MΩ for Vout = 1.8 V

(3) Rx = 1.8 MΩ, Ry = 1 MΩ for Vout = 3.3 V

(4) For proper sequencing of output, enable of the LDOs are fed either from 1.2-V output from DCDC3 converter

if DVDDX is 1.8 V or from 1.8-V output from DCDC2 converter if DVDDX is 3.3 V.

Figure 2. Optional circuit for DVDD_A, DVDD_B and DVDD_C

List of Material

Table 1. PMP4977 List of Material

Count

RefDes

Value

10 mF

Description

Size

Part Number

C2012X5R0J106K

C1608X5R0J225K

C2012X5R0J106K

C1608X5R0J105K

C2012X5R0J106K

C1608X5R0J105K

C1608X7R1H152K

C1608X5R0J225K

C2012X5R0J106K

C1608X5R0J105K

PTC36SAAN

MFR

TDK

Area

10560

Capacitor, Ceramic, 6.3V, X5R, 10%

Capacitor, Ceramic, 6.3V, X5R,10%

Capacitor, Ceramic, 6.3V, X5R, 10%

Capacitor, Ceramic, 6.3V, X5R,10%

Capacitor, Ceramic, 50V, X7R, 10%

Capacitor, Ceramic, 6.3V, X5R,10%

Capacitor, Ceramic, 6.3V, X5R, 10%

Capacitor, Ceramic, 6.3V, X5R,10%

Header, 2 pin, 100mil spacing, (36-pin strip)

805

603

805

603

805

603

805

603

10 mF

2.2 F

TDK

Sullins

10560

5650

2.2 F

5650

10 F

10560

5650

10 F

1.0 F

5650

10 F

10560

5650

C10

C11

C12

C13

C14

C15

C16

C17

10 F

1.0 F

1500 pF

2.2 F

5650

2.2 F

5650

10 F

10560

5650

10 F

1.0 F

PTC36SAAN

PEC36SAAN

0.100 x 2

23100

60000

Header, Male 5-pin, 100mil spacing, (36-pin

strip)

0.100 inch x 5

PEC36SAAN

PTC36SAAN

22-05-3041

Header, 2 pin, 100mil spacing, (36-pin strip)

Header, 4 pin, 100mil spacing, (36-pin strip)

Header, 2 pin, 100mil spacing, (36-pin strip)

0.100 x 2

PTC36SAAN

22-05-3041

Sullins

Molex

23100

45100

23100

227,900

0.100 x 4

0.100 x 2

Header, Friction Lock Ass'y, 4 pin Right

Angle

0.400 x 0.500

2.2 mH

Inductor, SMT, 1.72A, 59 mΩ

0.157 x 0.157 inch VLCF4020T-2R2N1R7

TDK

36.8

SLVA340A–June 2009–Revised May 2010

High-Integration, High-Efficiency Power Solution Using DC/DC Converters With

DVFS

List of Material

www.ti.com

Table 1. PMP4977 List of Material (continued)

Count

RefDes

Value

2.2 mH

Description

Inductor, SMT, 1.5A, 87 mΩ

Transistor, NPN, 40V, 200mA, 625mW

Resistor, Chip, 1/16W, 1%

Size

Part Number

MFR

TDK

Area

29320

37800

9100

111,600

0.137 X 0.147 inch VLF4012AT-2R2M1R5

2N3904

10k

TO-92

603

2N3904

Fairchild

Vishay

Std

2N3904

CRCW0603-xxxx-F

10k

603

CRCW0603-xxxx-F

10k

603

CRCW0603-xxxx-F

10k

603

CRCW0603-xxxx-F

100k

603

CRCW0603-xxxx-F

603

CRCW0603-xxxx-F

603

Std

603

Std

1.65M

499k

49.9k

100k

4.75k

603

Std

R10

R11

R12

R13

R14

R15

R16

R17

R18

R19

SW1

603

Std

603

Std

603

Std

603

Std

603

Std

603

Std

603

Std

603

Std

603

Std

603

Std

KT11P2JM

Switch, SPST, PB Momentary, Sealed

Washable

0.245 X 0.251

KT11P2JM

C & K

TPS65023RSB IC, Power Management IC for Li-Ion

Powered Systems

QFN

TPS65023RSB

69696

Notes: 1. These assemblies are ESD sensitive, ESD precautions shall be observed.

2. These assemblies must be clean and free from flux and all contaminants.

Use of no clean flux is not acceptable.

3. These assemblies must comply with workmanship standards IPC-A-610 Class 2.

4. Ref designators marked with an asterisk ('**') cannot be substituted.

All other components can be substituted with equivalent MFG's components.

High-Integration, High-Efficiency Power Solution Using DC/DC Converters With

DVFS

SLVA340A–June 2009–Revised May 2010

www.ti.com

List of Material

4.1 Test Results

The start-up waveform shown in Figure 3 specifies the required sequence.

Figure 3. Shows Sequencing in Start-Up Waveform

100

V = 2.5 V

V = 3.6 V

V = 4.2 V

V = 5 V

= 25°C

= 1.2 V

= 1.8 V

PWM/PFM Mode

0.01

0.1

100 1 k

10 k

0.01

0.1

100

1 k

10 k

- Output Current - mA

Figure 4. DCDC1: Efficiency vs Output Current

Figure 5. DCDC2: Efficiency vs Output Current

SLVA340A–June 2009–Revised May 2010

High-Integration, High-Efficiency Power Solution Using DC/DC Converters With

DVFS

List of Material

www.ti.com

100

90 V = 3.6 V

V = 2.5 V

V = 4.2 V

V = 5 V

= 25°C

= 1.8 V

PWM/PFM Mode

0.01

0.1

100

1 k

10 k

- Output Current - mA

Figure 6. DCDC3: Efficiency vs Output Current

High-Integration, High-Efficiency Power Solution Using DC/DC Converters With

DVFS

SLVA340A–June 2009–Revised May 2010

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C1608X7R1H152K [TI]

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