TPS53219ARGTT [TI]

Wide Input Voltage, Eco-modeâ¢, Single Synchronous Step-Down Controller; 宽输入电压，生态modeâ ?? ¢ ，单同步降压型控制器


型号：	TPS53219ARGTT
厂家：	TEXAS INSTRUMENTS
描述：	Wide Input Voltage, Eco-modeâ¢, Single Synchronous Step-Down Controller 宽输入电压，生态modeâ ?? ¢ ，单同步降压型控制器控制器
文件：	总26页 (文件大小：1060K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

TPS53219A

www.ti.com

SLUSAU4 –DECEMBER 2011

Wide Input Voltage, Eco-mode™, Single Synchronous Step-Down Controller

Check for Samples: TPS53219A

FEATURES

POINT-OF-LOAD APPLICATIONS

•

Conversion Input Voltage Range: 3 V to 28 V

VDD Input Voltage Range: 4.5 V to 25 V

Output Voltage Range: 0.6 V to 5.5 V

Wide Output Load Range: 0 A to > 20 A

Built-In 0.6-V (±0.8%) Reference

•

Storage Computer

Server Computer

•

Multi-Function Printer

Embedded Computing

DESCRIPTION

The TPS53219A is

Built-In LDO Linear Voltage Regulator

a small-sized single buck

Auto-Skip Eco-mode™ for Light-Load

controller with adaptive on-time D-CAP™ mode

control. The device is suitable for low output voltage,

high current, PC system power rail and similar

point-of-load (POL) power supplies in digital

consumer products. The small package and minimal

pin-count save space on the PCB, while the

dedicated EN pin and pre-set frequency selections

simplify the power supply design. The skip-mode at

light load conditions, strong gate drivers and low-side

FET R_DS(on)current sensing supports low-loss and

high efficiency, over a broad load range. The

conversion input voltage (high-side FET drain

voltage) range is between 4.5 V and 25 V, and the

output voltage range is between 0.6 V and 5.5 V. The

TPS53219A is available in a 16-pin, QFN package

specified from –40°C to 85°C.

Efficiency

•

D-CAP™ Mode with 100-ns Load-Step

Response

Adaptive On-Time Control Architecture with 8

Selectable Frequency Settings

•

4700ppm/°C R_DS(on)Current Sensing

0.7-ms, 1.4-ms, 2.8-ms and 5.6-ms Selectable

Internal Voltage Servo Soft-Start

•

Pre-Charged Start-up Capability

Built-In Output Discharge

Open-Drain Power Good Output

Integrated Boost Switch

Built-in OVP/UVP/OCP

Thermal Shutdown (Non-latch)

3 mm × 3 mm QFN, 16-Pin (RGT) Package

V_OUT

V_IN

VREG

VIN

CSD86350

PGOOD NC VBST DRVH

SW 12

TRIP

DRVL 11

VDRV 10

TPS53219A

VFB

TGR

VREG

Pad MODE VDD

GND PGND

PGND

UDG-11273

VDD

Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas

Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.

Eco-mode, D-CAP are trademarks of Texas Instruments.

PRODUCTION DATA information is current as of publication date.

Products conform to specifications per the terms of the Texas

Instruments standard warranty. Production processing does not

necessarily include testing of all parameters.

TPS53219A

SLUSAU4 –DECEMBER 2011

www.ti.com

These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam

during storage or handling to prevent electrostatic damage to the MOS gates.

ORDERING INFORMATION

ORDERING DEVICE

NUMBER

MINIMUM

QUANTITY

PACKAGE

PINS

OUTPUT SUPPLY

ECO PLAN

TPS53219ARGTR

TPS53219ARGTT

Tape and reel

Mini-reel

3000

250

Green (RoHS and

no Pb/Br)

–40°C to 85°C Plastic QFN (RGT)

ABSOLUTE MAXIMUM RATINGS⁽¹⁾

over operating free-air temperature range (unless otherwise noted)

VALUE

–0.3 to 37

–0.3 to 7

–0.3 to 28

–2.0 to 30

–7

UNIT

VBST

VBST⁽²⁾

VDD

Input voltage range

Pulse <20ns, E = 5 µJ

VDRV, EN, TRIP, VFB, RF, MODE

DRVH

DRVH⁽²⁾

Output voltage range

DRVL, VREG

–0.3 to 7

–2.0 to 37

–0.3 to 7

–0.5 to 7

–0.3 to 7

150

PGOOD

T_J

Junction temperature range

Storage temperature range

°C

T_STG

–55 to 150

(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 under "recommended operating

conditions" is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.

(2) Voltage values are with respect to the SW terminal

THERMAL INFORMATION

TPS53219A

THERMAL METRIC⁽¹⁾

UNITS

16-PIN RGT

51.3

θ_JA

Junction-to-ambient thermal resistance

θ_JCtop

θ_JB

Junction-to-case (top) thermal resistance

Junction-to-board thermal resistance

85.4

20.1

°C/W

ψ_JT

Junction-to-top characterization parameter

Junction-to-board characterization parameter

Junction-to-case (bottom) thermal resistance

1.3

ψ_JB

19.4

θ_JCbot

6.0

(1) For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.

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SLUSAU4 –DECEMBER 2011

RECOMMENDED OPERATING CONDITIONS

over operating free-air temperature range (unless otherwise noted)

MIN

–0.1

4.5

TYP

MAX

34.5

UNIT

VBST

VDD

Input voltage range

VBST⁽¹⁾

–1.0

–0.1

–1.0

–0.1

–0.3

–0.1

–40

6.5

34.5

6.5

EN, TRIP, VFB, RF, VDRV, MODE

DRVH

DRVH⁽¹⁾

Output voltage range

T_A

DRVL, VREG

PGOOD

Operating free-air temperature

°C

(1) Voltage values are with respect to the SW terminal.

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ELECTRICAL CHARACTERISTICS

over operating free-air temperature range, VDD = 12 V (Unless otherwise noted)

PARAMETER

SUPPLY CURRENT

CONDITIONS

MIN

TYP

MAX UNIT

VDD current, T_A= 25°C, No Load, V_EN= 5 V,

V_VFB= 0.630 V

I_VDD

VDD supply current

420

590

µA

I_VDDSDN

VDD shutdown current

VDD current, T_A=25°C, No Load, V_EN=0 V

INTERNAL REFERENCE VOLTAGE

V_VFB

I_VFB

VFB regulation voltage

VFB input current

VFB voltage, CCM condition⁽¹⁾

T_A= 25°C

600

µA

597

595.2

594

603

604.8

606

0°C ≤ T_A≤ 85°C

600.0

600

-40°C ≤ T_A≤ 85°C

V_VFB= 0.630V, T_A= 25°C

0.002

0.200

OUTPUT DRIVERS

Source, I_DRVH= –50 mA

Sink, I_DRVH= 50 mA

Source, I_DRVL= –50 mA

Sink, I_DRVL= 50 mA

1.5

0.7

1.0

0.5

1.8

2.2

1.2

R_DRVH

R_DRVL

t_DEAD

DRVH resistance

DRVL resistance

Dead time

DRVH-off to DRVL-on

DRVL-off to DRVH-on

LDO OUTPUT

V_VREG

I_VREG

V_DO

LDO output voltage

LDO output current⁽¹⁾

0 mA ≤ I_VREG≤ 50 mA

5.76

6.20

6.67

Maximum current allowed from LDO

V_VDD= 4.5 V, I_VREG= 50 mA

LDO drop out voltage

364

BOOT STRAP SWITCH

V_FBST

Forward voltage

VBST leakagecurrent

V_VREG-VBST, I_F= 10 mA, T_A= 25°C

V_VBST= 23 V, V_SW= 17 V, T_A= 25°C

0.1

0.2

1.5

I_VBSTLK

0.01

µA

DUTY AND FREQUENCY CONTROL

t_OFF(min)

t_ON(min)

SOFTSTART

Minimum off-time

T_A= 25°C

150

260

400

V_IN= 17 V, V_OUT= 0.6 V, R_RF= 0 Ω to VREG,

T_A= 25°C⁽¹⁾

Minimum on-time

0 V ≤ V_OUT≤ 95%, R_MODE= 39 kΩ

0 V ≤ V_OUT≤ 95%, R_MODE= 100kΩ

0 V ≤ V_OUT≤ 95%, R_MODE= 200 kΩ

0 V ≤ V_OUT≤ 95%, R_MODE= 470 kΩ

0.7

1.4

2.8

5.6

t_SS

Internal soft-start time

POWERGOOD

PG in from lower

PG in from higher

PG hysteresis

92.5%

108%

2.5%

96.0%

111%

5.0%

98.5%

114%

7.8%

V_THPG

PG threshold

PG transistor

on-resistance

R_PG

t_PG(del)

PG delay after soft-start

0.8

1.2

(1) Ensured by design. Not production tested.

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SLUSAU4 –DECEMBER 2011

ELECTRICAL CHARACTERISTICS

over operating free-air temperature range, VDD = 12 V (Unless otherwise noted)

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

LOGIC THRESHOLD AND SETTING CONDITIONS

–40°C ≤ T_A≤ 85°C

1.8

1.7

EN voltage threshold enable

V_EN

0°C ≤ T_A≤ 85°C

EN voltage threshold disable

0.5

1.0

I_EN

EN input current

V_EN= 5 V

µA

R_RF= 0 Ω to GND, T_A= 25°C⁽¹⁾

R_RF= 187 kΩ to GND, T_A= 25°C⁽¹⁾

R_RF= 619 kΩ to GND, T_A= 25°C⁽¹⁾

R_RF= Open, T_A= 25°C⁽¹⁾

R_RF= 866 kΩ to V_REG, T_A= 25°C⁽¹⁾

R_RF= 309 kΩ to V_REG, T_A= 25°C⁽¹⁾

R_RF= 124 kΩ to V_REG, T_A= 25°C⁽¹⁾

R_RF= 0 Ω to V_REG, T_A= 25°C⁽¹⁾

200

250

350

450

580

670

770

880

250

300

400

500

650

750

850

970

300

350

450

550

720

820

930

1070

f_SW

Switching frequency

kHz

VO DISCHARGE

I_Dischg

VO discharge current

V_EN= 0 V, V_SW= 0.5 V

PROTECTION: CURRENT SENSE

I_TRIP

TRIP source current

V_TRIP= 1 V, T_A= 25°C

T_A= 25°C⁽²⁾

µA

ppm/°C

TC_ITRIP

V_TRIP

TRIP current temp. coef.

4700

Current limit threshold setting range V_TRIP-GNDvoltage

V_TRIP= 3.0 V

0.2

355

185

395

215

375

200

V_OCL

Current limit threshold

V_TRIP= 1.6 V

V_TRIP= 0.2 V

V_TRIP= 3.0 V

V_TRIP= 1.6 V

V_TRIP= 0.2 V

Positive

–406

–215

–33

–375

–200

–25

–355

–185

–17

V_OCLN

Negative current limit threshold

Auto zero cross adjustable range

V_AZC(adj)

Negative

–15

–3

PROTECTION: UVP AND OVP

V_OVP

OVP trip threshold voltage

OVP detect

115% 120% 125%

t_OVP(del)

V_UVP

OVP propagation delay time

VFB delay with 50-mV overdrive

UVP detect

µs

Output UVP trip threshold voltage

Output UVP propagation delay time

Output UVP enable delay time

65%

0.8

70%

75%

1.2

t_UVP(del)

t_UVP(en)

UVLO

from EN to UVP workable, R_MODE= 39 kΩ

2.00

2.55

3.00

Wake up

4.00

4.18

0.25

4.50

V_UVVREG

VREG UVLO threshold

Hysteresis

THERMAL SHUTDOWN

T_SDNThermal shutdown threshold

Shutdown temperature⁽²⁾

Hysteresis⁽²⁾

145

°C

(1) Not production tested. Test conditions are V_IN= 12 V, V_OUT= 1.1 V, I_OUT=10 A and using the application circuit shown in Figure 17 and

Figure 18.

(2) Ensured by design. Not production tested

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DEVICE INFORMATION

RGT PACKAGE

16 PINS

(TOP VIEW)

TRIP

DVRL

VDRV

VREG

TPS53219A

VFB

PIN FUNCTIONS

NAME

NO.

DESCRIPTION

I/O/P⁽¹⁾

High-side MOSFET driver output. The SW node referenced floating driver. The gate drive voltage is defined

by the voltage across VBST to SW node bootstrap flying capacitor.

DRVH

Synchronous MOSFET driver output. The PGND referenced driver. The gate drive voltage is defined by

VDRV voltage.

DRVL

Enable pin. Place a 1-kΩ resistor in series with this pin if the source voltage is higher than 5.5 V.

GND

Ground pin. This is the ground of internal analog circuitry. Connect to GND plane at single point.

Soft-start and skip/CCM selection. Connect a resistor to select soft-start time using Table 1 . The soft-start

time is detected and stored into internal register during start-up.

MODE

–

No connection.

Open drain power good flag. Provides 1-ms start up delay after the VFB pin voltage falls within specified

limits. When VFB goes out specified limits PGOOD goes low after a 2-µs delay.

PGOOD

PGND

Power ground. Connect to GND plane.

Switching frequency selection. Connect a resistor to GND or VREG to select switching frequency using

Table 2. The switching frequency is detected and stored during the startup.

Output of converted power. Connect this pin to the output inductor.

OCL detection threshold setting pin. 10 µA at room temp, 4700ppm/°C current is sourced and set the OCL

trip voltage as follows.

TRIP

V_OCL=V_TRIP/8 spacer ( V_TRIP≤ 3 V, V_OCL≤ 375 mV)

Supply input for high-side FET gate driver (boost terminal). Connect a capacitor from this pin to SW-node.

Internally connected to VREG via bootstrap MOSFET switch.

VBST

VDD

VDRV

VFB

Controller power supply input. The input range is from 4.5 V to 25 V.

Gate drive supply voltage input. Connect to VREG if using LDO output as gate drive supply.

Output feedback input. Connect this pin to V_OUTthrough a resistor divider.

6.2-V LDO output. This is the supply of internal analog circuitry and driver circuitry.

Thermal pad. Use five vias to connect to GND plane.

VREG

Pad

–

(1) I=Input, O=Output, P=Power, G=Ground

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SLUSAU4 –DECEMBER 2011

FUNCTIONAL BLOCK DIAGRAM

16 PGOOD

0.6 V –30%

0.6 V +10/15%

Delay

0.6 V +20%

0.6 V –5/10%

Control Logic

Enable/SS Control

14 VBST

PWM

13 DRVH

12 SW

VFB

Ramp Comp

XCON

0.6 V

GND

TRIP

10 mA

OCP

t_ON

One-

Shot

x(-1/8)

FCCM

x(1/8)

10 VDRV

11 DRVL

Auto-skip

Auto-skip/FCCM

PGND

Frequency

Setting

Detector

LDO Linear

Regulator

TPS53219A

MODE

VREG

VDD

UDG-11274

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TYPICAL CHARACTERISTICS

700

600

500

400

300

200

100

5.0

4.5

4.0

3.5

3.0

2.5

2.0

1.5

No Load

1.0

0.5

0.0

V_EN= 5 V

V_VDD= 12 V

V_VFB= 0.63 V

No Load

V_EN= 0 V

V_VDD= 12 V

−50

−25

100

125

150

−50

−25

100

125

150

Temperature (°C)

Figure 1. VDD Supply Current vs Temperature

Figure 2. VDD Shutdown Current vs Temperature

140

120

100

OVP

UVP

V_VDD= 12 V

100 125 150

−50

−25

100

125

150

−25

Temperature (°C)

Figure 3. OVP/UVP Threshold vs Temperature

Figure 4. TRIP Pin Current vs Temperature

1000

100

1000

100

f_SET= 300 kHz

V_IN= 12 V

V_OUT= 1.1 V

f_SET= 500 kHz

V_IN= 12 V

V_OUT= 1.1 V

FCC Mode

Skip Mode

FCC Mode

Skip Mode

0.01

0.1

100

0.1

100

Output Current (A)

Figure 5. Switching Frequency vs Output Current

Figure 6. Switching Frequency vs Output Current

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TYPICAL CHARACTERISTICS (continued)

1000

100

f_SET=750 kHz

V_IN= 12 V

V_OUT= 1.1 V

f_SET=1 MHz

V_IN= 12 V

V_OUT= 1.1 V

FCC Mode

Skip Mode

FCC Mode

Skip Mode

0.01

0.1

100

0.01

0.1

100

Output Current (A)

Figure 7. Switching Frequency vs Output Current

Figure 8. Switching Frequency vs Output Current

1200

1000

800

600

400

200

1.120

f_SET= 500 kHz

V_IN= 12 V

V_OUT= 1.1 V

f_SET= 1 MHz

1.115

1.110

1.105

1.100

1.095

1.090

1.085

1.080

f_SET= 750 kHz

f_SET= 500 kHz

f_SET= 300 kHz

I_OUT=10 A

V_IN= 12 V

FCC Mode

Skip Mode

Output Voltage (V)

Output Current (A)

Figure 9. Switching Frequency vs Output Voltage

Figure 10. Output Voltage vs Output Current

1.110

1.108

1.106

1.104

1.102

1.100

1.098

1.096

1.094

1.092

1.090

100

V_IN= 12 V

V_OUT= 1.1 V

Skip Mode, f_SW= 500 kHz

FCC Mode, f_SW= 500 kHz

Skip Mode, f_SW= 300 kHz

FCC Mode, f_SW= 300 kHz

FCC Mode, No Load

Skip Mode, No Load

All Modes, I_OUT= 20 A

f_SW= 500 kHz

12 13 14 15

0.01

0.1

100

Input Voltage (V)

Output Current (A)

Figure 11. Output Voltage vs Input Voltage

Figure 12. Efficiency vs Output Current

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TYPICAL CHARACTERISTICS (continued)

Figure 13. Start up Waveform)

Figure 14. Pre-bias Start up Waveform)

Figure 15. Turn Off Waveform

Figure 16. Load Transient Response

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APPLICATION CIRCUIT DIAGRAM

R10

100 kW

0 W

VREG

V_IN

PGOOD

C_IN

VIN

0.1 mF

CSD86350

8.25 kW

22 mF x 4

DRVH

PGOOD NC

VBST

28.7 kW

TRIP

SW 12

0.44 mH

PA0513.441

R11

DRVL 11

VDRV 10

1 kW

V_OUT

TPS53219A

TGR

C_OUT

VFB

POSCAP

330 mF x 2

PGND

VREG

GND PGND Pad

MODE

VDD

10 kW

4.7 mF

187 kW

1 mF

100 kW

UDG-11275

PGOOD

VDD

Figure 17. Typical Application Circuit Diagram with Power Block

8.25 kW

V_IN

R10

100 kW

0 W

C_IN

22 mF x 4

VREG

PGOOD

1 nF

VIN

0.1 mF

CSD86350

0.1 mF

DRVH

PGOOD NC

VBST

28.7 kW

10 kW

TRIP

SW 12

0.44 mH

PA0513.441

R11

DRVL 11

VDRV 10

1 kW

V_OUT

C_OUT

TPS53219A

TGR

VFB

Ceramic

100 mF x 4

PGND

R12

VREG

GND PGND Pad

0 W

MODE

VDD

10 kW

187 kW

1 mF

4.7 mF

100 kW

UDG-11276

PGOOD

VDD

Figure 18. Typical Application Circuit Diagram with Ceramic Output Capacitors

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TPS53219A

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General Description

The TPS53219A is a high-efficiency, single channel, synchronous buck regulator controller suitable for low output

voltage point-of-load applications in computing and similar digital consumer applications. The device features

proprietary D-CAP™ mode control combined with an adaptive on-time architecture. This combination is ideal for

building modern low duty ratio, ultra-fast load step response DC-DC converters. The output voltage ranges from

0.6 V to 5.5 V. The conversion input voltage range is from 3 V up to 28V. The D-CAP™ mode uses the ESR of

the output capacitor(s) to sense the device current . One advantage of this control scheme is that it does not

require an external phase compensation network. This allows a simple design with a low external component

count. Eight preset switching frequency values can be chosen using a resistor connected from the RF pin to

ground or VREG. Adaptive on-time control tracks the preset switching frequency over a wide input and output

voltage range while allowing the switching frequency to increase at the step-up of the load.

The TPS53219A has a MODE pin to select between auto-skip mode and forced continuous conduction mode

(FCCM) for light load conditions. The MODE pin also sets the selectable soft-start time ranging from 0.7 ms to

5.6 ms as shown in Table 1. The strong gate drivers allow low R_DS(on)FETs for high-current applications.

When the device starts (either by EN or VDD UVLO), the TPS53219A sends out a current that detects the

resistance connected to the MODE pin to determine the soft-start time. After that (and before V_OUTstart to ramp

up) the MODE pin becomes a high-impedance input to determine skip mode or FCCM mode operation. When

the voltage on the MODE pin is higher than 1.3 V, the converter enters into FCCM mode. If the voltage on

MODE pin is less than 1.3 V, then the converter operates in skip mode.

It is recommended to connect the MODE pin to the PGOOD pin if FCCM mode is desired. In this configuration,

the MODE pin is connected to the GND potential through a resistor when the device is detecting the soft-start

time thus correct soft-start time is used. The device starts up in skip mode and only after the PGOOD pin goes

high does the device enter into FCCM mode. When the PGOOD pin goes high there is a transition between skip

mode and FCCM. A minimum off-time of 60 ns on DRVL is provided to avoid a voltage spike on the DRVL pin

caused by parasitic inductance of the driver loop and gate capacitance of the low-side MOSFET.

For proper operation, the MODE pin must not be connected directly to a voltage source.

Enable and Soft-Start

When the EN pin voltage rises above the enable threshold voltage (typically 1.4 V), the controller enters its

start-up sequence. The internal LDO regulator starts immediately and regulates to 6.2 V at the VREG pin. The

controller then uses the first 250 µs to calibrate the switching frequency setting resistance attached to the RF pin

and stores the switching frequency code in internal registers. However, switching is inhibited during this phase. In

the second phase, an internal DAC starts ramping up the reference voltage from 0 V to 0.6 V. Depending on the

MODE pin setting, the ramping up time varies from 0.7 ms to 5.6 ms. Smooth and constant ramp-up of the

output voltage is maintained during start-up regardless of load current.

Table 1. Soft-Start and MODE

MODE

SELECTION

SOFT-START

TIME (ms)

ACTION

R_MODE(kΩ)

0.7

1.4

2.8

5.6

0.7

1.4

2.8

5.6

100

200

475

Auto Skip

Pull down to GND

100

200

475

(1)

Forced CCM

Connect to PGOOD

(1) Device goes into Forced CCM after PGOOD becomes high.

When the EN voltage is higher than 5.5 V, a 1-kΩ series resistor is needed for EN pin

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Adaptive On-Time D-CAP™ Control and Frequency Selection

The TPS53219A does not have a dedicated oscillator that determines switching frequency. However, the device

operates with pseudo-constant frequency by feed-forwarding the input and output voltages into the on-time

one-shot timer. The adaptive on-time control adjusts the on-time to be inversely proportional to the input voltage

and proportional to the output voltage (t_ON∝ V_OUT/V_IN).

This makes the switching frequency fairly constant in steady state conditions over a wide input voltage range.

The switching frequency is selectable from eight preset values by a resistor connected between the RF pin and

GND or between the RF pin and the VREG pin as shown in Table 2. (Leaving the resistance open sets the

switching frequency to 500 kHz.)

Table 2. Resistor and Switching Frequency

SWITCHING

RESISTOR (R_RF) CONNECTIONS

FREQUENCY (kHz)

0 Ω to GND

250

300

400

500

650

750

850

970

187 kΩ to GND

619 kΩ to GND

Open

866 kΩ to VREG

309 kΩ to VREG

124 kΩ to VREG

0 Ω to VREG

The off-time is modulated by a PWM comparator. The VFB node voltage (the mid-point of resistor divider) is

compared to the internal 0.6-V reference voltage added with a ramp signal. When both signals match, the PWM

comparator asserts a set signal to terminate the off time (turn off the low-side MOSFET and turn on high-side

MOSFET). The set signal is valid if the inductor current level is below the OCP threshold, otherwise the off time

is extended until the current level falls below the threshold.

Small Signal Model

From small-signal loop analysis, a buck converter using D-CAP™ mode can be simplified as shown in Figure 19.

V_IN

TPS53219A

Switching Modulator

DRVH

VFB

V_OUT

PWM

Control

Logic

and

DRVL

I_OUT

I_IND

Driver

I_C

0.6 V

ESR

R_LOAD

Voltage Divider

V_C

C_OUT

Output

Capacitor

UDG-11277

Figure 19. Simplified Modulator Model

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The output voltage is compared with the internal reference voltage (ramp signal is ignored here for simplicity).

The PWM comparator determines the timing to turn on the high-side MOSFET. The gain and speed of the

comparator can be assumed high enough to keep the voltage at the beginning of each on cycle substantially

constant.

H s =

( )

s´ESR ´C

OUT

(1)

For the loop stability, the 0 dB frequency, ƒ₀, defined below must be lower than ¼ of the switching frequency.

f =

2p´ESR ´C

OUT

(2)

According to the equation above, the loop stability of D-CAP™ mode modulator is mainly determined by the

capacitor chemistry. For example, specialty polymer capacitors (SP-CAP) have an output capacitance on the

order of several 100 µF and ESR in range of 10 mΩ. These yields an f₀on the order of 100 kHz or less and a

more stable loop. However, ceramic capacitors have an ƒ₀at more than 700 kHz, and require special care when

used with this modulator. An application circuit for ceramic capacitor is described in section External Parts

Selection with All Ceramic Output Capacitors.

Ramp Signal

The TPS53219A adds a ramp signal to the 0.6-V reference in order to improve jitter performance. As described

in the previous section, the feedback voltage is compared with the reference information to keep the output

voltage in regulation. By adding a small ramp signal to the reference, the S/N ratio at the onset of a new

switching cycle is improved. Therefore the operation becomes less jittery and more stable. The ramp signal is

controlled to start with –7 mV at the beginning of an on-cycle and becomes 0 mV at the end of an off-cycle in

steady state.

During skip mode operation, when the switching frequency is lower than 70% of the nominal frequency (because

of longer off-time), the ramp signal exceeds 0 mV at the end of the off-time but is clamped at 3 mV to minimize

DC offset.

Light Load Condition in Auto-Skip Operation

While the MODE pin is pulled low via R_MODE, TPS53219A automatically reduces the switching frequency at light

load conditions to maintain high efficiency. Detailed operation is described as follows. As the output current

decreases from heavy load condition, the inductor current is also reduced and eventually comes to the point that

its rippled valley touches zero level, which is the boundary between continuous conduction and discontinuous

conduction modes. The synchronous MOSFET is turned off when this zero inductor current is detected. As the

load current further decreases, the converter runs into discontinuous conduction mode (DCM). The on-time is

kept almost the same as it was in the continuous conduction mode so that it takes longer time to discharge the

output capacitor with smaller load current to the level of the reference voltage. The transition point to the light

load operation I_O(LL)(i.e., the threshold between continuous and discontinuous conduction mode) can be

calculated as shown in Equation 3.

- V

´ V

(

)

OUT OUT

OUT LL

( )

2´L ´ f

where

•

ƒ_SWis the PWM switching frequency

(3)

Switching frequency versus output current in the light load condition is a function of L, V_INand V_OUT, but it

decreases almost proportionally to the output current from the IO_(LL)given in Equation 3. For example, it is 60

kHz at IO_(LL)/5 if the frequency setting is 300 kHz.

Adaptive Zero Crossing

The TPS53219A has an adaptive zero crossing circuit which performs optimization of the zero inductor current

detection at skip mode operation. This function pursues ideal low-side MOSFET turning off timing and

compensates inherent offset voltage of the Z-C comparator and delay time of the Z-C detection circuit. It

prevents SW-node swing-up caused by too late detection and minimizes diode conduction period caused by too

early detection. As a result, better light load efficiency is delivered.

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Forced Continuous Conduction Mode

When the MODE pin is tied to PGOOD through a resistor, the controller keeps continuous conduction mode

(CCM) in light load condition. In this mode, switching frequency is kept almost constant over the entire load

range which is suitable for applications need tight control of the switching frequency at a cost of lower efficiency.

Output Discharge Control

When EN becomes low, the TPS53219A discharges output capacitor using internal MOSFET connected

between the SW pin and the PGND pin while the high-side and low-side MOSFETs are maintained in the OFF

state. The typical discharge resistance is 40 Ω. The soft discharge occurs only as EN becomes low. After VREG

becomes low, the internal MOSFET turns off and the discharge function becomes inactive.

Low-Side Driver

The low-side driver is designed to drive high-current low-R_DS(on)N-channel MOSFET(s). The drive capability is

represented by its internal resistance, which is 1.0 Ω for VDRV to DRVL and 0.5 Ω for DRVL to GND. A dead

time to prevent shoot through is internally generated between high-side MOSFET off to low-side MOSFET on,

and low-side MOSFET off to high-side MOSFET on. The bias voltage VDRV can be delivered from 6.2 V VREG

supply or from external power source from 4.5 V to 6.5 V. The instantaneous drive current is supplied by an input

capacitor connected between the VDRV and PGND pins.

The average low-side gate drive current is calculated in Equation 4.

= C ´ V

´ f

VDRV SW

(4)

When VDRV is supplied by external voltage source, the device continues to be supplied by the VREG pin. There

is no internal connection from VDRV to VREG.

High-Side Driver

The high-side driver is designed to drive high current, low R_DS(on)N-channel MOSFET(s). When configured as a

floating driver, the bias voltage is delivered from the VDRV pin supply. The average drive current is calculated

using Equation 5.

= C ´ V

´ f

VDRV SW

(5)

The instantaneous drive current is supplied by the flying capacitor between VBST and SW pins. The drive

capability is represented by internal resistance, which is 1.5 Ω for VBST to DRVH and 0.7 Ω for DRVH to SW.

The driving power which needs to be dissipated from TPS53219A package.

P_DRV= I + I_GH´ V

)

(

VDRV

(6)

Power Good

The TPS53219A has power-good output that indicates high when switcher output is within the target. The

power-good function is activated after soft-start has finished. If the output voltage becomes within +10% or –5%

of the target value, internal comparators detect power-good state and the power-good signal becomes high after

a 1-ms internal delay. If the output voltage goes outside of +15% or –10% of the target value, the power-good

signal becomes low after two microsecond (2-µs) internal delay. The power-good output is an open drain output

and must be pulled up externally.

In order for the PGOOD logic to be valid, the VDD input must be higher than 1 V. To avoid invalid PGOOD logic

before the TPS53219A is powered up, it is recommended that the PGOOD pin be pulled-up to VREG (either

directly or through a resistor divider if a different pull-up voltage is desired) because VREG remains low when the

device is powered off. The pull-up resistance can be chosen from a standard resistor value between 1 kΩ and

100 kΩ.

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Current Sense and Overcurrent Protection

TPS53219A has cycle-by-cycle overcurrent limiting control. The inductor current is monitored during the OFF

state and the controller maintains the OFF state during the period in that the inductor current is larger than the

overcurrent trip level. In order to provide both good accuracy and cost effective solution, TPS53219A supports

temperature compensated MOSFET R_DS(on)sensing. The TRIP pin should be connected to GND through the trip

voltage setting resistor, R_TRIP. The TRIP terminal sources I_TRIPcurrent, which is 10 µA typically at room

temperature, and the trip level is set to the OCL trip voltage V_TRIPas shown in Equation 7. Note that the V_TRIPis

limited up to approximately 3 V internally.

mV = R

kW ´I

_TRIP( ) _TRIP( ) _TRIP( )

(7)

The inductor current is monitored by the voltage between GND pin and SW pin so that SW pin should be

connected to the drain terminal of the low-side MOSFET properly. I_TRIPhas 4700 ppm/°C temperature slope to

compensate the temperature dependency of the R_DS(on). The GND pin is used as the positive current sensing

node. The GND pin should be connected to the proper current sensing device, (for example, the source terminal

of the low-side MOSFET.)

As the comparison is done during the OFF state, V_TRIPsets the valley level of the inductor current. Thus, the load

current at the overcurrent threshold, I_OCP, can be calculated as shown in Equation 8.

- V

´ V

IND ripple

(

)

OUT OUT

TRIP

)

TRIP

OCP

2´L ´ f

8´R

DS on

)

(

DS on

( )

(8)

In an overcurrent condition, the current to the load exceeds the current to the output capacitor thus the output

voltage tends to fall down. Eventually, it crosses the undervoltage protection threshold and shuts down. After a

hiccup delay (16 ms with 0.7 ms sort-start), the controller restarts. If the overcurrent condition remains, the

procedure is repeated and the device enters hiccup mode.

During the CCM, the negative current limit (NCL) protects the external FET from carrying too much current. The

NCL detect threshold is set as the same absolute value as positive OCL but negative polarity. Note that the

threshold still represents the valley value of the inductor current.

Overvoltage and Undervoltage Protection

TPS53219A monitors a resistor divided feedback voltage to detect over and under voltage. When the feedback

voltage becomes lower than 70% of the target voltage, the UVP comparator output goes high and an internal

UVP delay counter begins counting. After 1ms, TPS53219A latches OFF both high-side and low-side MOSFETs

drivers. The controller restarts after a hiccup delay (16 ms with 0.7 ms soft-start). This function is enabled 1.5-ms

after the soft-start is completed.

When the feedback voltage becomes higher than 120% of the target voltage, the OVP comparator output goes

high and the circuit latches OFF the high-side MOSFET driver and latches ON the low-side MOSFET driver. The

output voltage decreases. If the output voltage reaches UV threshold, then both high-side MOSFET and low-side

MOSFET driver will be OFF and the device restarts after an hiccup delay. If the OV condition remains, both

high-side MOSFET and low-side MOSFET driver remains OFF until the OV condition is removed.

UVLO Protection

The TPS53219A uses VREG undervoltage lockout protection (UVLO). When the VREG voltage is lower than

3.95 V, the device shuts off. When the VREG voltage is higher than 4.2 V, the device restarts. This is non-latch

protection.

Thermal Shutdown

The TPS53219A uses temperature monitoring. If the temperature exceeds the threshold value (typically 145°C),

the device is shut off. This is non-latch protection.

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External Components Selection

Selecting external components is a simple process using D-CAP™ Mode.

1. CHOOSE THE INDUCTOR

The inductance should be determined to give the ripple current of approximately ¼ to ½ of maximum output

current. Larger ripple current increases output ripple voltage and improves the signal-to-noise ratio and helps

stable operation.

- V

´ V

)

- V

´ V

OUT OUT

)

(

max

(

OUT

(

max

(

)

L =

´ f

max

(

OUT

IND ripple

(

max

)

(

)

(

)

(9)

The inductor also requires a low DCR to achieve good efficiency. It also requires enough room above the peak

inductor current before saturation. The peak inductor current can be estimated in Equation 10.

- V

´ V

OUT

)

(

max

(

OUT

)

TRIP

IND peak

(

)

8´R

L ´ f

DS on

max

( )

(

(10)

2. CHOOSE THE OUTPUT CAPACITOR(S)

When organic semiconductor capacitor(s) or specialty polymer capacitor(s) are used, for loop stability,

capacitance and ESR should satisfy Equation 2. For jitter performance, Equation 11 is a good starting point to

determine ESR.

V_OUT´10mV ´(1-D) 10mV ´L ´ f_SWL ´ f_SW

ESR =

( )

0.6V ´I

0.6V

IND ripple

(

)

where

•

D is the duty factor

•

the required output ripple slope is approximately 10 mV per t_SW(switching period) in terms of VFB terminal

voltage

(11)

3. DETERMINE THE VALUE OF R1 AND R2

The output voltage is programmed by the voltage-divider resistor, R1 and R2 shown in Figure 19. R1 is

connected between the VFB pin and the output, and R2 is connected between the VFB pin and GND.

Recommended R2 value is between 10 kΩ and 20 kΩ. Determine R1 using Equation 12.

´ESR

IND ripple

(

)

V_OUT

- 0.6

R1=

´R2

0.6

(12)

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External Parts Selection with All Ceramic Output Capacitors

When a ceramic output capacitor is used, the stability criteria in Equation 2 cannot be satisfied. The ripple

injection approach as shown in Figure 18 is implemented to increase the ripple on the VFB pin and make the

system stable. C2 can be fixed at 1 nF. The value of C1 can be selected between 10 nF to 200 nF.

The increased ripple on the VFB pin causes the increase of the VFB DC value. The AC ripple coupled to the

VFB pin has two components, one coupled from SW node and the other coupled from V_OUTand they can be

calculated using Equation 13 and Equation 14.

- V

OUT

(

)

INJ SW

(

)

R7´ C1

(13)

(14)

IND ripple

(

)

= ESR´I

)

INJ OUT

(

IND ripple

(

)

8´ C_OUT´ f_SW

The DC value of VFB can be calculated by Equation 15.

+ V

)

(

= 0.6 +

INJ SW

(

INJ OUT

(

)

(15)

(16)

And the resistor divider value can be determined by Equation 16.

- V

(

)

OUT

R1=

´R2

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LAYOUT CONSIDERATIONS:

Certain points must be considered before starting a layout work using the TPS53219A.

•

Inductor, V_INcapacitor(s), V_OUTcapacitor(s) and MOSFETs are the power components and should be placed

on one side of the PCB (solder side). Other small signal components should be placed on another side

(component side). At least one inner plane should be inserted, connected to power ground, in order to shield

and isolate the small signal traces from noisy power lines.

•

All sensitive analog traces and components such as VFB, PGOOD, TRIP, MODE and RF should be placed

away from high-voltage switching nodes such as SW, DRVL, DRVH or VBST to avoid coupling. Use internal

layer(s) as ground plane(s) and shield feedback trace from power traces and components.

The DC/DC converter has several high-current loops. The area of these loops should be minimized in order to

suppress generating switching noise.

–

The most important loop to minimize the area of is the path from the V_INcapacitor(s) through the high and

low-side MOSFETs, and back to the capacitor(s) through ground. Connect the negative node of the V_IN

capacitor(s) and the source of the low-side MOSFET at ground as close as possible.

The second important loop is the path from the low-side MOSFET through inductor and V_OUTcapacitor(s),

and back to source of the low-side MOSFET through ground. Connect source of the low-side MOSFET

and negative node of VOUT capacitor(s) at ground as close as possible.

The third important loop is of gate driving system for the low-side MOSFET. To turn on the low-side

MOSFET, high current flows from VDRV capacitor through gate driver and the low-side MOSFET, and

back to negative node of the capacitor through ground. To turn off the low-side MOSFET, high current

flows from gate of the low-side MOSFET through the gate driver and PGND of the device, and back to

source of the low-side MOSFET through ground. Connect negative node of VDRV capacitor, source of the

low-side MOSFET and PGND of the device at ground as close as possible.

•

Because the TPS53219A controls output voltage referring to voltage across V_OUTcapacitor, the high-side

resistor of the voltage divider should be connected to the positive node of V_OUTcapacitor at the regulatioin

point. The low-side resistor should be connected to the GND (analog ground of the device). The traceꢀfrom

these resistors to the VFB pin should be short and thin. Place on the component side and avoid via(s)

between these resistors and the device.

•

Connect the overcurrent setting resistors from the TRIP pin to GND and make the connections as close as

possible to the device. The trace from TRIP pin to resistor and from resistor to GND should avoid coupling to

a high-voltage switching node.

Connect the frequency setting resistor from RF pin to GND, or to the PGOOD pin, and make the connections

as close as possible to the device. The trace from the RF pin to the resistor and from the resistor to GND

should avoid coupling to a high-voltage switching node.

•

Connect all GND (analog ground of the device) trace together and connect to power ground or ground plane

with a single via or trace or through a 0-Ω resistor at a quiet point

Connections from gate drivers to the respective gate of the high-side or the low-side MOSFET should be as

short as possible to reduce stray inductance. Use 0.65 mm (25 mils) or wider traceꢀand via(s) of at least 0.5

mm (20 mils) diameter along this trace.

•

The PCB trace defined as switch node, which connects to source of high-side MOSFET, drain of low-side

MOSFET and high-voltage side of the inductor, should be as short and wide as possible.

Connect the ripple injection V_OUTsignal (V_OUTside of the C1 capacitor in Figure 18) from the terminal of

ceramic output capacitor. The AC coupling capacitor (C7 in Figure 18 ) can be placed near the device.

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PACKAGE OPTION ADDENDUM

www.ti.com

31-Dec-2011

PACKAGING INFORMATION

Status ⁽¹⁾

Eco Plan ⁽²⁾

MSL Peak Temp ⁽³⁾

Samples

Orderable Device

Package Type Package

Drawing

Pins

Package Qty

Lead/

Ball Finish

(Requires Login)

TPS53219ARGTR

TPS53219ARGTT

ACTIVE

QFN

RGT

3000

250

Green (RoHS

& no Sb/Br)

CU NIPDAU Level-2-260C-1 YEAR

Green (RoHS

& no Sb/Br)

CU NIPDAU Level-2-260C-1 YEAR

⁽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⁾Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability

information and additional product content details.

TBD: The Pb-Free/Green conversion plan has not been defined.

Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that

lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.

Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between

the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.

Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight

in homogeneous material)

⁽³⁾MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.

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 MATERIALS INFORMATION

www.ti.com

14-Jul-2012

TAPE AND REEL INFORMATION

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

Pin1

Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant

(mm) W1 (mm)

TPS53219ARGTR

TPS53219ARGTT

QFN

RGT

3000

250

330.0

180.0

12.4

3.3

1.1

8.0

12.0

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

14-Jul-2012

*All dimensions are nominal

Device

Package Type Package Drawing Pins

SPQ

Length (mm) Width (mm) Height (mm)

TPS53219ARGTR

TPS53219ARGTT

QFN

RGT

3000

250

367.0

210.0

367.0

185.0

35.0

Pack Materials-Page 2

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TPS53311RGTR

TPS53311RGTT

TPS53311_1

TPS53313

TPS53313RGER