AT1309 [AIMTRON]

Micro-Power Step up DC-DC Converter; 微功率升压升压DC -DC转换器


型号：	AT1309
厂家：	AIMTRON TECHNOLOGY
描述：	Micro-Power Step up DC-DC Converter 微功率升压升压DC -DC转换器转换器
文件：	总14页 (文件大小：287K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Feature

Description

The AT1309 step-up converter is designed for small

or medium size LCD panel of high bias voltage with

a constant current to provide PDAs, and other

hand-held devices. It features a fast 1.4 MHz

current-mode PWM control with a built-in 0.3Ω

N-MOS that allows for smaller capacitor and

inductor. Fault condition protection uses cycle-by

-cycle current limiting to sense maximum inductor

current and thermal protection. Also included

soft-start eliminates inrush current during start-up.

•Operating Voltage:2.5V to 6.0V.

•High Operating Frequency: 1.4MHz

•High Output Voltage: Up to 28V

•Shutdown Current <1µA

•Digital Dimming Control.

•Built-in Cycle-by Cycle Current-Limiting.

•Built-in Soft-Start Function.

•±1.5% 1.23V Reference Voltage

•Tiny SOT-25 Package

The AT1309 is available in 5-pin SOT-25 packages.

Application

• STN/OLED Bias

• Personal Digital Assistants(PDAs)

• DSC

Block Diagram

Aimtron reserves the right without notice to change this circuitry and specifications.

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Pin Configuration

Ordering Information

Part number

Package

Marking

AT1309X

SOT-25

Date Code

AT1309X_GRE

SOT-25, Green

,Date Code with one bottom line

: Date Code

*For more marking information, contact our sales representative directly

Pin Description

Pin N0. Symbol I / O

Description

Step-up Regulator N-MOS Drain. Place output diode and inductor.

Ground

GND

Step-Up Regulator Feedback Input. Connect a sense resistor from FB to

ground.

Enable and Dimming Control Input. LED brightness and IC shutdown are

controlled by the voltage on EN. Driving low for longer than 4ms to

shutdown the IC.

VIN

Power supply.

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Absolute Maximum Ratings*1

Parameter

Rated Value

-0.3 to +6.5

Unit

VIN voltage

LX voltage

-0.3 to +30

-0.3 to +6.5

1.8

EN , FB to GND

Switch Current (I_LX)

Continuous power dissipation (SOT-25 Ta=+25^OC)

Operating Junction Temperature Range

Lead Temperature (Soldering 5 sec)

Storage Temperature

0.25

-30 to 85

260

℃

℃/W

-65 to 125

250

Package Thermal Resistance (Θ_JA)

ESD Susceptibility*2

HBM

200

1. Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the

device. These are stress ratings only, and functional operation of the device at these or any other

conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure

to absolute maximum rating conditions for extended periods may affect device reliability.

2. Device are ESD sensitive. Handling precaution recommended. The Human Body model is a 100pF

capacitor discharged through a 1.5KΩ resistor into each pin.

Recommended Operation Conditions

Parameter

Symbol

Values

Typ.

Unit

Min.

2.5

Max.

6.0

Power supply voltage

Operating temperature

V_IN

Top

─

℃

-20

+25

+85

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Electrical Characteristics

(V_IN=2.5V, Ta=+25℃, unless otherwise noted)

Parameter

Symbol

Test Condition

V_INinput Voltage

Min. Typ. Max. Units

Operating V _INRange

V_IN

2.5

6.0

2.3

Under Voltage Thershold

Switch- Off Input Current

Shutdown Current

UVLO V_INfalling, 100mV hysteresis 2.1

2.2

µA

I_IN1

I_IN3

V_FB

I_FB

No Switching

EN=0V

100 120

Feedback Reference

1.212 1.230 1.248

FB Input Bias Current

V_FB=0.2V

µA

2.5V< V_IN<6.0V

Output Voltage Line Regulation

Switching Frequency

Maximum Duty

0.1

1.4

f_OSC

D_MAX

t_SS

MHz

Soft-Start charging time

0.5

Switching Current Limit

V_IN=3.0V,duty cycle=80%

1.0

=350mA

LX ON Resistance

LX Leakage Current

EN Input Current

R_LX

I_Leakage

I_EN

0.3

V_LX=28V, EN=0V

µA

EN=5V

0.1V hysteresis

V_IH

2.0

EN Input Level

V_IL

0.8

EN low Shutdown Delay

Thermal Shutdown

℃

120

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Typical Characteristics

Efficiency vs. VIN

Efficiency vs. Load current

100

Vo=15V

L=10uH

Vo=15V

L=10uH

VIN=3V

IOUT=20mA

VIN=4V

VIN=5V

IOUT=50mA

IOUT=100mA

10 20 30 40 50 60 70 80 90 100 110

2.5

3.5

4.5

5.5

Load current

VIN(V)

Quiescent current vs. VIN

Efficiency vs. Load current

200

190

180

170

160

150

140

130

120

110

100

Vo=15V

Vin=3.0V

TA=25^OC

L=22uH

L=10uH

10 20 30 40 50 60 70 80 90 100 110

2.5

3.5

4.5

5.5

Load current

VIN (V)

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Load Transient Response

VIN=3.0V, Vout=15V, L=10uH, Iout=10mA to 100mA

Ch1:Vout (AC mode), Ch4:Iout, Time:0.2ms/div

Line Transient Response

VIN=3.0V to 6.0V, Vout=15V, L=10uH, Iout=100mA

Ch1:VIN, Ch2:Vout (AC mode), Ch3:I_IN, Time:0.5s/div

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Start up Waveform with Load

VIN=3.0V, Vout=15V, L=10uH, Iout=100mA

Ch1:Vout, Ch2:EN, Ch3:I_IN, Time:5ms/div

LX Switching Waveform

VIN=3.0V, Vout=15V, L=10uH

Ch1:LX, Ch3:I_LX, Time:0.5us/div

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Application Circuit

MBR0530

-15V/4mA

1uF

MBR0530

4.7uH

VIN

15V/4mA

2.5V to 5.0V

MBR0530

4u7F

VIN

20pF

1uF

AT1309

180K

16K

GND

Fig3. ±15V Dual Output Converter

10uH

15V/100mA

VIN

3.0V to 5.0V

SS24

10uF

VIN

10uF

20pF

AT1309

180K

16K

GND

Fig4. 15V Boost Converter

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Function Description

The AT1309 is designed primarily for use in STN/OLED bias applications. The output

voltage of the step-up converter can be set from Vin to 26V with external resistive

voltage divider. The boost converter operates in current-mode PWM and a constant

frequency of 1.0 MHz. Depending on duty cycle of each switching cycle can regulate

output voltage. On the rising edge of the internal clock, the control and driver logic

block sets internal flip-flop when the output voltage is too low, which turns on the

N-MOS. The external inductor current ramps up linearly, storing energy in a magnetic

filed. Once peak current of inductor over trans-conductance output level, the N-MOS

turns off, the flip-flop resets, and external schottky diode turns on . This forces the

current through the inductor to ramp back down, transferring the energy stored in the

magnetic field to the output capacitor and load. To reduce external component amount,

the device will be built-in internal loop compensation.

Enable Control

Digital logic of EN provides an electrical ON/OFF control of the power supply.

Connecting this pin to ground or to any voltage less than 0.7V will completely turn

OFF the regulator. In this state, current drain from the input supply is less than 1µA,

the internal reference, error amplifier, comparators, and biasing circuitry turn off .

EN works as a simple on/off control. Drive EN high to enable the device, or drive EN

low for shutdown.

Soft-Start

Soft-start allows a gradual increase of the internal current-limit level for the step-up

converter during power-up to reduce input surge currents. As the internal current

source charges the internal soft-start capacitor, the peak N-MOS current is limited by

the voltage on the capacitor.

Cycle-by-Cycle Over-Current Protection

The AT1309 provides cycle-by-cycle over-current protection. Current limit is

accomplished using a separate dedicated comparator. The cycle-by-cycle current limit

abbreviates the on-time of the N-MOS in event that the current of flowing N-MOS is

greater than the current limit value. The current-limit feature protection against a hard

short or over-current fault at the output.

Thermal-Overload Protection

Thermal-overload protection limits total power dissipation in the AT1309. When the

junction temperature exceeds Tj=130 ℃, a thermal sensor activates the thermal

protection, which shuts down the IC, allowing the IC to cool. Once the device cools

down by 10 ℃, IC will automatically recover normal operation. For continuous

operation , do not exceed the absolute maximum junction-temperature rating of

Tj=120 ℃.

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Power dissipation consideration

The AT1309 maximum power dissipation depends on the thermal resistance of the IC

package and circuit board, the temperature difference between the die junction and

ambient air, and the rate of any airflow. The power dissipation in the device depends

on the operating conditions of the regulator. In continuous condition, the step-up

converter power dissipated internally across the internal N-MOS can be approximated

by :

I_O×V

V_in

V_in× D

12 f_OSC× L

= [(

^O)²+

(

)²]× R_{DS(ON )}× D

boost

where

I_O: It is the load current.

f_OSC: It is a switching frequency.

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Application Information

External components of boost converter can be designed by performing simple

calculations.

Boost inductor

Inductor selection depends on input voltage, output voltage, maximum output current,

switching frequency and availability of inductor values. The following boost circuit

equations are useful in choosing the inductor values based on the application. They

allow the trading of peak current and inductor value while allowing for consideration

of component availability and cost.

The peak inductor current is given by:

∆I_L

I_Lpeak= I_LAVG

I_O

I_LAVG

1− D

where:

△I_Lis the inductor peak-to-peak current ripple and is decided by:

V_in

∆I_L=

f_OSC

D is the MOSFET turn on ratio and is decided by:

V_O−V _in

D =

V_O

f_OSCis the switching frequency.

The inductor should be chosen to be able to handle this current and inductor saturation

current rating should be greater than I_PEAK

Diode selection

The output diode has average current of I_O, and peak current the same as the

inductor’s peak current and a voltage rating at least 1.5 times the output voltage.

Schottky diode is recommended and it should be able to handle those current.

Output Capacitor

The AT1308 is specially compensated to be stable with capacitors which have a worst-

case minimum value of 1uF at the particular V_OUTbeing set. Output ripple voltage

requirements also determine the minimum value and type of capacitors. Output ripple

voltage consists of two components the voltage drop caused by the switching current

through the ESR of the output capacitor and the charging and discharging of the

output capacitor:

V_O−V_in

I_O

V_RIPPLE= I_LPEAK× ESR +

V_O

C_OUT× f_OSC

For low ESR ceramic capacitors, the output ripple is dominated by the charging or

discharging of the output capacitor.

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Impacting frequency stability of the overall control loop, Ceramic capacitors are

preferred on the output capacitance, but tantalum capacitor may also suffice. If it use

tantalum capacitor on the output terminal, that in addition the capacitance parallel

with feedback resistor network is necessary. These frequency response effects

together with the internal frequency compensation circuitry of AT1308 modify the

gain and phase shift of the closed loop system.

PCB layout guidelines

Careful printed circuit layout is extremely important to avoid causing parasitical

capacitance and line inductance. The following layout guidelines are recommended to

achieve optimum performance.

‧ Please the boost converter diode and inductor close to the LX pin and no via.

Keep traces short, direct, and wide.

‧ Please ceramic bypass capacitors near the input/output pin.

‧ Locate all feedback sense resistors as close to the feedback pins as possible.

‧ The ground connections of V_INand V_OUTshould be as close together as possible.

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Small Outline SOT-25

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309

Preliminary Product Information

Micro-Power Step up DC-DC Converter

Reflow Profiles

Profile Feature

Sn-Pb Eutectic Assembly

Pb-Free Assembly

Large Body

Pkg. thickness

≥2.5mm or Pkg.

volume ≥350mm³

Small Body

Pkg. thickness

<2.5mm or Pkg.

volume <350mm³

Large Body

Pkg. thickness

Small Body

Pkg. thickness

≥2.5mm or Pkg.

volume ≥350mm³volume ≥350mm³

3°C/second max.

Average ramp-up rate

3°C/second max.

(T to T )

Preheat

-Temperature Min(Tsmin)

-Temperature Max (Tsmax)

-Time (min to max)(ts)

100°C

150°C

60-120 seconds

150°C

200°C

60-180 seconds

3°C/second max.

Tsmax to T

-Ramp-up Rate

Time maintained above:

-Temperature (T )

-Time (t )

183°C

60-150 seconds

217°C

60-150 seconds

Peak Temperature(T )

225+0/-5°C

10-30 seconds

240+0/-5°C

10-30 seconds

245+0/-5°C

10-30 seconds

250+0/-5°C

20-40 seconds

Time within 5°C of actual Peak

Temperature (t )

Ramp-down Rate

6°C/second max.

6 minutes max.

3°C/second max.

8 minutes max.

Time

25°C

Peak

Temperature

*All temperatures refer to topside of the package, measured on the package body surface.

7F, No.9, PARK AVENUE II, Science-Based Industrial Park, Hsinchu 300,Taiwan, R.O.C.

Tel: 886-3-563-0878

3/2/2006 REV:1.1

Fax: 886-3-563-0879

WWW: http://www.aimtron.com.tw

Email: service@aimtron.com.tw

AT1309 [AIMTRON]

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