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TPS92560DGQ/NOPB

更新时间：2025-05-03 05:35:14

品牌：TI

描述：适用于 MR16 和 AR111 应用的简易 LED 驱动器 | DGQ | 10 | -40 to 125

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TPS92560DGQ/NOPB 概述

适用于 MR16 和 AR111 应用的简易 LED 驱动器 | DGQ | 10 | -40 to 125 LED驱动器显示驱动器

TPS92560DGQ/NOPB 规格参数

是否无铅：	不含铅	是否Rohs认证：	符合
生命周期：	Active	包装说明：	HTSSOP, TSSOP10,.19,20
Reach Compliance Code：	compliant	ECCN代码：	EAR99
HTS代码：	8542.39.00.01	风险等级：	1.63
输入特性：	STANDARD	接口集成电路类型：	LED DISPLAY DRIVER
JESD-30 代码：	S-PDSO-G10	JESD-609代码：	e3
长度：	3 mm	湿度敏感等级：	3
复用显示功能：	NO	功能数量：	1
区段数：	3	端子数量：	10
封装主体材料：	PLASTIC/EPOXY	封装代码：	HTSSOP
封装等效代码：	TSSOP10,.19,20	封装形状：	SQUARE
封装形式：	SMALL OUTLINE, HEAT SINK/SLUG, THIN PROFILE, SHRINK PITCH	峰值回流温度（摄氏度）：	260
电源：	12 V	认证状态：	Not Qualified
座面最大高度：	1.1 mm	子类别：	Display Drivers
最大压摆率：	1.95 mA	最大供电电压：	42 V
最小供电电压：	6.5 V	标称供电电压：	12 V
表面贴装：	YES	温度等级：	AUTOMOTIVE
端子面层：	Matte Tin (Sn)	端子形式：	GULL WING
端子节距：	0.5 mm	端子位置：	DUAL
处于峰值回流温度下的最长时间：	NOT SPECIFIED	宽度：	3 mm
Base Number Matches：	1

TPS92560DGQ/NOPB 数据手册

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TPS92560

www.ti.com

SNVS900A –DECEMBER 2012–REVISED JANUARY 2013

SIMPLE LED DRIVER FOR MR16 AND AR111 APPLICATIONS

Check for Samples: TPS92560

FEATURES

APPLICATIONS

•

Controlled peak input current to prevent over-

stressing of the electronic transformer

•

MR16/AR111 LED lamps

Lighting system using electronic transformer

•

Allows either step-up or step-up/down

operation

General lighting systems that require a boost /

SEPIC LED driver

•

Compatible to generic electronic transformers

DESCRIPTION

Compatible to magnetic transformers and DC

power supplies

The TPS92560 is a simple LED driver designed to

drive high power LEDs by drawing constant current

from the power source. The device is ideal for MR16

and AR111 applications which need good

compatibility to DC and AC voltages and electronic

transformers. The hysteretic control scheme does not

need control loop compensation while providing the

benefits of fast transient response and high power

factor. The patent pending feedback control method

allows the output power to be determined by the

number of LED used without component change. The

TPS92560 supports both boost and SEPIC

configurations for the use of different LED modules.

•

Integrated active low-side input rectifiers

Compact and simple circuit

>85% efficiency (12VDC input)

Power factor > 0.9 (full load with AC input)

Hysteretic control scheme

Output Over-Voltage Protection

Over-temperature Shutdown

10-pin mini SOIC package with exposed pad

TYPICAL APPLICATION

L₁

D₃

LED

C_IN

R_ADJ1

D₁

D₂

R₁

TPS92560

C_OUT

Q₁

GATE

AC1

PGND

AC2

R_ADJ2C_ADJ

Power

Source

SRC

VCC

SEN

GND

C_VCC

C_VP

ADJ

R_SEN

Typical application circuit of the TPS92560 using boost configuration

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.

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.

TPS92560

SNVS900A –DECEMBER 2012–REVISED JANUARY 2013

www.ti.com

TYPICAL APPLICATION (Continue)

L₁

D₃

C₁

LED

R_ADJ1

C_OUT

C_IN

R₁

D₁

D₂

TPS92560

Q₁

L₂

GATE

SRC

VCC

SEN

GND

AC1

PGND

AC2

R_ADJ2C_ADJ

Power

Source

C_VCC

C_VP

ADJ

R_SEN

D₄

Typical Application Circuit of the TPS92560 using SEPIC configuration

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Product Folder Links :TPS92560

TPS92560

www.ti.com

SNVS900A –DECEMBER 2012–REVISED JANUARY 2013

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.

BLOCK DIAGRAM

TPS92560

VCC

LDO

VCC

AC1

AC2

TSD

GATE

DRIVER

GATE

SRC

T_J=165°C

UVLO

VCC < 4.98V

Main Switch

and Rectifier

Control

SEN

VCC

DRV

VCC

DRV

Logic

GND

ADJ

OVP

0.384V

PGND

SVA-30207403

ORDERING INFORMATION

ORDER NUMBER

TPS92560DGQ

TPS92560DGQR

PACKAGE TYPE

NSC PACKAGE DRAWING

SUPPLIED AS

1000 Units on Tape and Reel

4500 Units on Tape and Reel

10L MINI SOIC EXP PAD

MUC10A

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Product Folder Links :TPS92560

TPS92560

SNVS900A –DECEMBER 2012–REVISED JANUARY 2013

www.ti.com

10-pin mini SOIC Package

(TOP VIEW)

GATE

AC1

SRC

VCC

SEN

PGND

AC2

GND

ADJ

Package Number MUC10A

SVA-30207405

TERMINAL FUNCTIONS

DESCRIPTION

NO. NAME

APPLICATION INFORMATION

GATE

SRC

VCC

Gate driver output pin

Gate driver return

Connect to the Gate terminal of the low-side N-channel Power FET

Connect to the Source terminal of the low-side N-channel Power FET

Connect 0.47μF decoupling cap from this pin to SRC pin

VCC regulator output

Kelvin-sense current sensing input. Should connect to the current sensing

resistor, R_SEN

SEN

Current sense pin

GND

ADJ

Analog ground

Reference point for current sensing.

LED current adjust pin

Connect to resistor divider from LED top voltage rail to set LED current

Connect it to the LED top voltage rail (for boost) or Connect it through a diode

from LED top voltage rail (for SEPIC)

Power supply of the IC

AC2

Power return terminal

Power ground

Connect to AC or DC input terminal

Connect to system ground plane

PGND

AC1

Power return terminal

Connect to AC or DC input terminal

Connect to system ground plane for heat dissipation

PowerPAD Thermal DAP

ABSOLUTE MAXIMUM RATINGS⁽¹⁾

If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/ Distributors for

availability and specifications.

VALUE

–0.3 to 5

–1 to 45

UNIT

SRC, SEN, ADJ

AC1, AC2

–0.3 to 45

–0.3 to 12

1.5

VCC

ESD Rating Human Body Model⁽²⁾

°C

Storage Temperature

–65 to +150

–40 to +125

T_J

Junction Temperature

(1) Absolute Maximum Ratings are limits which damage to the device may occur. Operating ratings are conditions under which operation of

the device is intended to be functional. For specified specifications and test conditions, see the electrical characteristics.

(2) The human body model is a 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin.

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TPS92560

www.ti.com

SNVS900A –DECEMBER 2012–REVISED JANUARY 2013

RECOMMENDED OPERATING CONDITIONS

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

MIN

6.5

NOM

MAX

UNIT

T_J

Supply voltage range

Junction temperature range

–40

125

°C

(1)

θ_JA

θ_JC

Thermal resistance, Junction to Ambient, 0 LFPM Air Flow

Thermal resistance, Junction to Case

°C/W

(1) θ_JAand θ_JCmeasurements are performed on JEDEC boards in accordance with JESD 51-5 and JESD 51-7

ELECTRICAL CHARACTERISTICS

Specification with standard type are for T_A=T_J= 25°C only; limits in boldface type apply over the full Operating Junction

Temperature (T_J) range. Minimum and Maximum are specified through test, design or statistical correlation. Typical values

represent the most likely parametric norm at T_J= 25°C, and are provided for reference purposes only. Unless otherwise stated

the following conditions apply: V_VP= 12V

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

SUPPLY

I_IN

V_INOperating current

6.5 V < V_VP< 42 V

0.7

1.4

1.95

VCC REGULATOR

_CC≤ 10mA, C_VCC=0.47µF

7.82

8.45

9.08

6.18

12V < V_VP< 42V

V_CC

V_CCRegulated Voltage⁽¹⁾

I_CC= 10mA, C_VCC=0.47µF V_VP= 6.5V

I_CC= 0mA, C_VCC=0.47µF V_VP= 2V

V_CC= 0V 6.5V < V_VP< 42V

5.22

1.96

5.8

2.0

I_CC-LIM

V_CCCurrent Limit

5.76

5.33

640

V_CC-UVLO-UPTH

V_CC-UVLO-LOTH

V_CC-UVLO-HYS

V_CCUVLO Upper Threshold

V_CCUVLO Lower Threshold

V_CCUVLO Hysteresis

5.0

5.38

4.98

400

4.63

190

MOSFET GATE DRIVER

w.r.t. SRC

V_GATE-HIGHGate Driver Output High

Sinking 100mA from GATE

Force VCC = 8.5V

7.61

100

8.1

8.5

w.r.t. SRC

Sourcing 100mA to GATE

V_GATE-LOW

Gate Driver Output Low

180

290

t_RISE

V_GATERise Time

C_GATE= 1nF across GATE and SRC

t_FALL

V_GATEFall Time

t_{RISE-PG-DELAY}

t_{FALL-PG-DELAY}

V_GATELow to High Propagation Delay

V_GATEHigh to Low Propagation Delay

CURRENT SOURCE AT ADJ PIN

I_ADJ-STARTUP

I_ADJ-ELEC-XFR

I_ADJ-MAG-XFR

Output Current of ADJ pin at Startup

V_ADJ= 0V

11.5

9.5

µA

Output Current of ADJ pin for Electronic

Transformers

An Electronic Transformer is Detected

Output Current of ADJ pin for Inductive An Magnetic Transformer is Detected

Transformers

CURRENT SENSE COMPARATOR

V_SEN-UPPER-THV_SENUpper Threshold Over V_ADJ

V_SEN-LOWER-TH

V_SEN-V_ADJ, V_ADJ=0.2V, V_GATEat falling

edge

8.9

14.9

20.9

–8.8

V_SEN-V_ADJ, V_ADJ=0.2V V_GATEat rising

edge

V_SENLower Threshold Over VADJ

–20.6 –14.9

V_SEN-HYS

V_SENHysteresis

(V_SEN-UPPER-TH- V_SEN-LOWER-TH

)

22.5

–3.5

29.8

0.02

37.5

3.5

V_SEN-OFFSET

V_SENOffset w.r.t. V_ADJ

(V_SEN-UPPER-TH+ V_SEN-LOWER-TH)/2

ACTIVE low-side input rectifiers

R_ACn-ONIn resistance of AC1 and AC2 to GND

I_ACn= 200mA

300

570

mΩ

(1) V_CCprovides self bias for the internal gate drive and control circuits. Device thermal limitations limit external loading.

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Product Folder Links :TPS92560

TPS92560

SNVS900A –DECEMBER 2012–REVISED JANUARY 2013

www.ti.com

ELECTRICAL CHARACTERISTICS (continued)

Specification with standard type are for T_A=T_J= 25°C only; limits in boldface type apply over the full Operating Junction

Temperature (T_J) range. Minimum and Maximum are specified through test, design or statistical correlation. Typical values

represent the most likely parametric norm at T_J= 25°C, and are provided for reference purposes only. Unless otherwise stated

the following conditions apply: V_VP= 12V

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

Turn ON Voltage Threshold of AC1 and

AC2

V_ACn-ON-TH

V_ACn-OFF-TH

V_ACnDecreasing

Turn OFF Voltage Threshold of AC1

and AC2

V_ACnIncreasing

104

V_ACn-TH-HYS

I_ACn-OFF

Hysteresis Voltage of AC1 and AC2

Off Current of AC1 and AC2

V_ACn-OFF-TH- V_ACn-ON-TH

V_ACn= 45V

µA

OUTPUT OVER-VOLTAGE-PROTECTION (OVP)

Output Over-Voltage-Detection Upper

V_ADJ-OVP-UPTH

Threshold

V_ADJIncreasing, V_GATEat falling edge

V_ADJDecreasing, V_GATEat rising edge

V_ADJ-OVP-UPTH- V_ADJ-OVP-LOTH

0.353 0.384 0.415

0.312 0.339 0.366

Output Over-Voltage-Detection Lower

V_ADJ-OVP-LOTH

Threshold

Output Over-Voltage-Detection

V_ADJ-OVP-HYS

Hysteresis

THERMAL SHUTDOWN

T_SD

Thermal Shutdown Temperature

T_JRising

T_JFalling

165

°C

Thermal Shutdown Temperature

Hysteresis

T_SD-HYS

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TPS92560

www.ti.com

SNVS900A –DECEMBER 2012–REVISED JANUARY 2013

TYPICAL CHARACTERISTICS

All curves taken for the boost circuit are with 500mA nominal input current and 6 serial LEDs. All curves taken for the SEPIC

circuit are with 500mA nominal input current and 3 serial LEDs.T_A= –40°C to 125°C, unless otherwise specified.

Operation Current vs. Temperature

VCC vs. Temperature (I_CC= 0mA)

1.6

1.5

1.4

1.3

1.2

1.1

8.45

8.4

V_VP=42V

8.35

8.3

V_VP=12V

V_VP=6.5V

V_VP=12V

8.25

8.2

8.15

-40

-20

100 120 140

-40

-20

100 120 140

C001

C002

Ambient Temperature, T_A(°C)

Figure 1.

Figure 2.

VCC UVLO Rising Threshold vs. Temperature

V_VP=12V, GATE='Hi'

VCC UVLO Falling Threshold vs. Temperature

V_VP=12V, GATE='Low'

5.42

5.4

5.02

5.38

5.36

5.34

5.32

5.3

4.98

4.96

4.94

4.92

-40

-20

100 120 140

-40

-20

100 120 140

C003

C004

Ambient Temperature, T_A(°C)

Figure 3.

Figure 4.

ACn Turn OFF Threshold vs. Temperature

ACn Turn ON Threshold vs. Temperature

140

120

100

-40

-20

100 120 140

-40

-20

100 120 140

C005

C006

Temperature, T_A(°C)

Ambient Temperature, T_A(°C)

Figure 5.

Figure 6.

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Product Folder Links :TPS92560

TPS92560

SNVS900A –DECEMBER 2012–REVISED JANUARY 2013

www.ti.com

TYPICAL CHARACTERISTICS (continued)

All curves taken for the boost circuit are with 500mA nominal input current and 6 serial LEDs. All curves taken for the SEPIC

circuit are with 500mA nominal input current and 3 serial LEDs.T_A= –40°C to 125°C, unless otherwise specified.

Output Current (BOOST) vs. Temperature

Output Current (SEPIC) vs. Temperature

0.7

0.6

0.5

0.4

0.3

0.2

0.1

0.9

0.8

0.7

0.6

0.5

0.4

0.3

0.2

0.1

V_IN=12V

-40

-20

100 120 140

-40

-20

100 120 140

C007

C008

Ambient Temperature, T_A(°C)

Figure 7.

Figure 8.

Output Power (BOOST) vs. Temperature

Output Power (SEPIC) vs. Temperature

V_IN=12V

-20

100 120 140

-20

100 120 140

C009

C010

Ambient Temperature, T_A(°C)

Figure 9.

Figure 10.

Efficiency (BOOST) vs. Temperature

Efficiency (SEPIC) vs. Temperature

100

V_IN=18V

V_IN=15V

V_IN=18V

V_IN=15V

V_IN=12V

V_IN=9V

V_IN=6V

V_IN=9V

V_IN=6V

-20

100 120 140

-20

100 120 140

C011

C012

Ambient Temperature, T_A(°C)

Figure 11.

Figure 12.

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TPS92560

www.ti.com

SNVS900A –DECEMBER 2012–REVISED JANUARY 2013

OVERVIEW

The TPS92560 is a simple hysteretic control switching LED driver for MR16 or AR111 lighting applications. The

device accepts DC voltage, AC voltage and electronic transformer as an input power source. The compact

application circuit can fit into a generic case of MR16 lamps easily. The hysteretic inductor current control

scheme requires no small signal control loop compensation and maintains constant average input current to

secure high compatibility to different kinds of input power source. The TPS92560 can be configured to either a

step-up or step-up/down LED driver for the use of different number of LEDs. The patent pending current control

mechanism allows the use of a single set of component and PCB layout for serving different output power

requirements by changing the number of LEDs. The integrating of the active low-side input rectifiers reduces the

power loss for voltage rectification and saves two external diodes of a generic bridge rectifier to aim for a simple

end application circuit. When the driver is used with an AC voltage source or electronic transformer, the current

regulation level increases accordingly to maintain an output current close to the level that when it is used with a

DC voltage source. With the output over-voltage protection and over-temperature shutdown functions, the

TPS92560 is specifically suitable for the applications that are space limited and need wide acceptance to

different power sources.

VCC REGULATOR

The VCC pin is the output of the internal linear regulator for providing an 8.45V typical supply voltage to the

MOSFET driver and internal circuits. The output current of the VCC pin is limited to 30mA typical. A low ESR

ceramic capacitor of 0.47μF or higher capacitance should be connected across the VCC and SRC pins to supply

transient current to the MOSFET driver.

MOSFET DRIVER

The GATE pin is the output of the gate driver which referenced to the SRC pin. The gate driver is powered

directly by the VCC regulator which the maximum gate driving current is limited to 30mA typical. To prevent

hitting the VCC current limit, it is suggested to use a low gate charge MOSFET when high switching frequency is

needed.

THE ADJ PIN

The voltage on the ADJ pin determines the reference voltage for the input current regulation. Typically, the ADJ

pin voltage is divided from the output voltage of the circuit by a voltage divider, thus the average input current is

adjusted with respect to the number of LEDs used. The voltage of the ADJ pin determines the input current

following the expression:

V_VP

R_SEN

R_ADJ2

R_ADJ1+ R_ADJ2

I_IN(nom)

(1)

Output Over-Voltage-Protection

In the TPS92560, a function of output Over-Voltage Protection (OVP) is provided to prevent damaging of the

circuit due to an open circuit of the LED. The OVP function is implemented to the ADJ pin. When the voltage of

the ADJ pin exceeds 0.384V typical, the OVP circuit disables the MOSFET driver and turns off the main switch to

allow the output capacitor to discharge. As the voltage of the ADJ pin decreases to below 0.353V typical, the

MOSFET driver is enabled and the TPS92560 returns to normal operation. The triggering threshold of the output

voltage is determined by the value of the resistors R_ADJ1and R_ADJ2, which can be calculated using the following

equation:

R_ADJ2

R_ADJ1+ R_ADJ2

V_VP

≤ 0.384V

(2)

When defining the OVP threshold voltage, it is necessary to certain that the OVP threshold voltage does not

exceed the rated voltage of the output rectifier and capacitor to avoid damaging of the circuit.

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TPS92560

SNVS900A –DECEMBER 2012–REVISED JANUARY 2013

www.ti.com

THE AC1 AND AC2 PINS

The TPS92560 provides two internal active rectifiers for input voltage rectification. Each internal rectifier connects

across the ACn pin to GND. These internal active rectifiers function as the low-side diode rectifiers of a generic

bridge rectifier. The integrating of the active rectifiers helps in saving two external diodes of a bridge rectifier

along with an improvement of power efficiency. For high power applications, for instance, 12W output power,

external diode rectifiers can be added across the ACn pin to GND to reduce heat dissipation on the TPS92560.

DETECTION OF POWER SOURCE

V_IN(From elect. transformer)

12V × 2

Time

Switching period

Dead time

of the elect. transformer

1/50Hz or 1/60Hz

Figure 13. The inherent dead time of the output voltage of an electronic transformer

Both the voltages of a generic AC source (50/60Hz) and an electronic transformer carry certain amount of dead

time inherently, as shown in Figure 13. The existing of the dead time leads to a drop of the RMS input power to

the driver circuit. In order to compensate the drop of the RMS input power, the ADJ pin sources current to the

resistor, R_ADJ2to increase the reference voltage for the current regulation loop and in turn increase the RMS

input power accordingly when an AC voltage source or electronic transformer is detected. The output current of

the ADJ pin for an AC input voltage and electronic transformer are 9.5μA and 11.5μA typical respectively.

Practically the amount of the power for compensating the dead time of the input power source differs case to

case depending on the characteristics of the power source, the value of the R_ADJ1and R_ADJ2might need a fine

adjustment in accordance to the characteristics of the power source. The additional output power for

compensating the dead time of the power sources (ΔP_LED) are calculated using the following equations:

For 50/60Hz AC power source:

R_ADJ2´ 9.5 mA

= V ´

´ h

LED-50/60 Hz

R_SEN

(3)

(4)

For electronic transformer:

R_ADJ2´11.5 mA

= V ´

´ h

LED-ELECT-XFR

R_SEN

CURRENT REGULATION

In the TPS92560, the input current regulation is attained by limiting the peak and valley of the inductor current.

Practically the inductor current sensing is facilitated by detecting the voltage on the resistor, R_SEN. Because the

current flows through the R_SENis a sum total of the currents of the main switch and LEDs, the voltage drop on

the R_SENreflects the current of the inductor that is identical to the input current to the LED driver circuit.

Figure 14 shows the waveform of the inductor current ripple with the peak and valley values controlled.

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TPS92560

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SNVS900A –DECEMBER 2012–REVISED JANUARY 2013

I_L

t_ON

t_OFF

Switch off

I_L(peak)

V_SEN-UPPER-TH

R_SEN

Time

V_SEN-LOWER-TH

R_SEN

Switch on

I_L(valley)

t_{FALL-PG-DELAY}t_{RISE-PG-DELAY}

SVA-30207404

Figure 14. Inductor Current Ripple in Steady State

The voltage of the ADJ pin is determined by the forward voltage of the LED and divided from the V_VPby a

resistor divider. The equation for calculating the V_ADJas shown in the following expression:

R_ADJ2

V_ADJ= V_VP

R_ADJ1+ R_ADJ2

(5)

In steady state, the voltage drop on the R_ADJ1is identical to the forward voltage of the LED (V_LED) and the voltage

across the R_ADJ2is identical to the voltage across the R_SEN. The LED current, I_LEDis then calculated following the

equations:

In steady state:

V_LED= V_RADJ1

V_SEN= V_RADJ2

V_SEN

(6)

(7)

I_IN(nom)

R_SEN

(8)

(9)

Since

P_LED= P_INx η

where η is the conversion efficiency

Thus,

V_LEDx I_LED= V_INx I_IN(nom)x η

(10)

Put the expressions (2) to (4) into (5):

I_ADJ2x R_ADJ2

I_LED= V_IN

x η

I_ADJ1x R_ADJ1x R_SEN

(11)

Due to the high input impedance of the ADJ pin, the current flows into the ADJ pin can be neglected and thus

I_RADJ1equals I_RADJ2. The LED current is then calculated following the expressions below:

R_ADJ2

x η

I_LED= V_IN

R_ADJ1x R_SEN

(12)

Practically, the conversion efficiency of a boost circuit is almost a constant around 85%. Being assumed that the

efficiency term in the I_LEDexpression is a constant, the LED current depends solely on the magnitude of the input

voltage, V_IN. Without changing a component, the output power of the typical application circuits of the TPS92560

is adjustable by using different number of LEDs.

The output power is calculated by following the expression:

R_ADJ2

P_LED= V_LEDx V_IN

x η

R_ADJ1x R_SEN

(13)

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SWITCHING FREQUENCY (Boost Configuration)

In the following sections, the equations and calculations are limited to the boost configuration only (i.e. the LED

forward voltage higher than the input voltage), unless otherwise specified. The application information for the

SEPIC and other circuit topologies are available in separate application notes and reference designs. In the

boost configuration, including the propagation delay of the control circuit, the ON and OFF times of the main

switch are calculated following the expressions:

V_SEN-UPPER-THx L

t_ON

+ t_{FALL-PG-DELAY}x 2

R_SENx [V_IN- V_D- I_IN(nom)x (R_L+ R_DS(ON)+R_SEN+ R_AC-FET)]

(14)

V_SEN-LOWER-THx L

t_OFF

+ t_{RISE-PG-DELAY}x 2

R_SENx [V_LED- V_IN- 2V_D- I_IN(nom)x (R_L+R_SEN+ R_AC-FET)]

(15)

In the above equations, the V_Dis the forward voltage of D₃, R_Lis the DC resistance of L₁, R_DS(ON)is the ON

resistance of Q₁and R_AC-FETis the turn ON resistance of the internal active rectifier with respect to the typical

application circuit diagram.

Practically the resistance of the R_L, R_DS(on)and R_AC-FETis in the order if serveral tenth of mΩ, by assuming a 0.5V

diode forward voltage and the sum total of the R_L, R_DS(ON)and R_AC-FETis close to 1Ω, the on and off times of Q₁

can be approximated using the following equations:

14.9mV x L

t_ON

≈

+ 84ns x 2

R_SENx [V_IN– 0.5V - I_IN(nom)x (1 + R_SEN)]

(16)

14.9mV x L

t_OFF

≈

+ 68ns x 2

R_SENx [V_LED- V_IN- 1V - I_IN(nom)x (1 + R_SEN)]

(17)

With the switching on and OF times determined, the switching frequency can be calculated using the following

equation:

f_SW

_ON+ t_OFF

(18)

Because of the using of hysteretic control scheme, the switching frequency of the TPS92560 in steady state is

dependent on the input voltage, output voltage and inductance of the inductor. Generally a 1 MHz to 1.5 MHz

switching frequency is suggested for applications using an electronic transformer as the power source.

INDUCTOR SELECTION (Boost Configuration)

Because of the using of the hysteretic control scheme, the switching frequency of the TPS92560 in a boost

configuration can be adjusted in accordance to the value of the inductor being used. Derived from the equations

(12) and (13), the value of the inductor can be determined base on the desired switching frequence by using the

following equation:









− 304ns ×R_SEN





f_SW



L =













× 29.8mV

_IN− 0.5V −I_IN(nom)×(1+ R_SEN

)

V_LED− V_IN−1V −I_IN(nom)×(1+ R_SEN)

(19)

When selecting the inductor, it is essential to ensure the peak inductor current does not exceed the the factory

suggested saturation current of the inductor. The values of the peak and valley inductor current are calculated

using the following equations:

Peak inductor current:

[V_IN- V_D- I_IN(nom)x (R_L+ R_DS(ON)+R_SEN+ R_AC-FET)] x t_ON

I_L(peak)

+ I_IN(nom)

(20)

Valley inductor current:

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[V_LED- V_IN- 2V_D- I_IN(nom)x (R_L+R_SEN+ R_AC-FET)] x t_OFF

I_L(valley)= I_IN(nom)

(21)

Assume the total resistance of the R_L, R_DS(on)and R_AC-FETis 1Ω and the diode drop, V_Dequal to 1V, the peak

and valley currents of the inductor can be approximated using the following equations:

[V_IN– 0.5V - I_IN(nom)x (1 + R_SEN)] x t_ON

I_L(peak)

≈

+ I_IN(nom)

(22)

(23)

[V_LED- V_IN- 1V - I_IN(nom)x (1 + R_SEN)] x t_OFF

I_L(valley)≈ I_IN(nom)

In order not to saturate the inductor, an inductor with a factory guranteed saturation current (I_SAT) 20% higher

than the I_L(peak)is suggested. Thus the I_SATof the inductor should fulfill the following requirement:

I_SAT≥ I_L(peak)x 1.2

(24)

THERMAL SHUTDOWN

The TPS92560 includes a thermal shutdown circuitry that ceases the operation of the device to avoid permanent

damage. The threshold for thermal shutdown is 165°C with a 30°C hysteresis typical. During thermal shutdown

the VCC regulator is disabled and the MOSFET is turned off.

INPUT SURGE VOLTAGE PROTECTION

When use with an electronic transformer, the surge voltage across the input terminals can be sufficiently high to

damage the TPS92560 depending on the charactistics of the electronic transformer. To against potential

damaging due to the input surge voltage, a 36V zener diode can be connected across the input bridge rectifier as

shown in Figure 15.

L₁

C_IN

36V

Zener

Diode

D₁

D₂

R₁

U₁

TPS92560

AC1

PGND

AC2

Power

Source

Figure 15. Input surge voltage protection using an external zener diode

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EXAMPLE APPLICATION CIRCUITS

In the applications that need true regulation of the LED current, the intrinsic input current control loop can be

changed to monitor the LED current by adding an external LED current sensing circuit. Figure 16 and Figure 19

show the example circuits for true LED current regulation in boost and SEPIC configurations respectively. In the

circuits, the U₃(TL431) maintains a constant 2.5V voltage drop on the resistors, R₃and R₇. Because the U₂

(TL431) maintains a constant voltage drop on the R₃, the power dissipation on the output current sensing

resistor, R₇can be minimized by setting a low voltage drop on the R₇. Because the change of the current flowing

through the R₇reflects in the change of the cathode current of U₃and eventually adjusts the ADJ pin voltage of

the TPS92560, the LED current is regulated independent of the change of the input voltage.

Boost Application Circuit with LED Current Regulation

The specifications of the boost application circuit in Figure 16 are as listed below:

•

Objective input voltage: 3VDC to 18VDC / 12VAC(50Hz or 60Hz) / Generic MR16 electronic transformer

LED forward voltage: 20VDC typical

Output current: 300mA typical (@12VDC input)

Output power: 6W typical (@12VDC input)

L₁

D₃

15µH

2A 40V

LED

C_IN

25V

1µF

Z₁

VCC

R₂

R₅

15k

36V

C_OUT1

35V

330µF

C_OUT

1µF

4.02k

R₁

105

D₁

D₂

VCC

2A 40V

Q₁

3A 60V

R₄

562

TPS92560

R₆

40.2k

U₂

U₃

TL431

GATE

AC1

Power

Source

TL431

SRC

VCC

SEN

GND

PGND

AC2

C₁

1µF

R₃

4.02k

C_VCC

1µF

R₇

R_ADJ2

C_ADJ

4.7µF

C_VP

47nF

ADJ

R_SEN

0.2

U₁

Figure 16. Using the TPS92560 in SEPIC configuration with LED current regulation

Typical Characteristics of the Boost Example Circuit in Figure 16

All curves taken at V_IN= 3V to 18VDC in boost configuration, with 300mA nominal output current, 6 serial LEDs.

T_A= 25°C.

LED Current vs. Input Voltage

Efficiency vs. Input Voltage

350

300

250

200

150

100

C017

C018

Input Voltage, V_IN(V)

Figure 17.

Figure 18.

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SEPIC Application Circuit with LED Current Regulation

The specifications of the SEPIC application circuit in Figure 16 are as listed below:

•

Objective input voltage: 3VDC to 18VDC / 12VAC(50Hz or 60Hz) / Generic MR16 electronic transformer

LED forward voltage: 13VDC typical

Output current: 300mA typical (@12VDC input)

Output power: 4W typical (@12VDC input)

C₂

L₁

D₃

15µH

1µF

2A 40V

LED

C_IN

25V

1µF

Z₁

VCC

R₂

R₅

1.82k

36V

C_OUT1

25V

330µF

C_OUT

4.7µF

4.02k

L₂

15µH

R₁

105

D₁

D₂

VCC

2A 40V

Q₁

3A 60V

R₄

562

TPS92560

R₆

36.5k

U₂

U₃

TL431

GATE

AC1

Power

Source

TL431

SRC

VCC

SEN

GND

PGND

AC2

C₁

1µF

R₃

4.02k

C_VCC

1µF

R₇

R_ADJ2

C_ADJ

4.7µF

C_VP

100nF

ADJ

R_SEN

0.3

U₁

D₄

600mA 40V

Figure 19. Using the TPS92560 in SEPIC configuration with LED current regulation

Typical Characteristics of the SEPIC Example Circuit in Figure 19

All curves taken at V_IN= 3V to 18VDC in SEPIC configuration, with 300mA nominal output current, 4 serial LEDs.

T_A= 25°C.

LED Current vs. Input Voltage

Efficiency vs. Input Voltage

350

300

250

200

150

100

C019

C020

Input Voltage, V_IN(V)

Figure 20.

Figure 21.

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PACKAGE OPTION ADDENDUM

www.ti.com

24-Jan-2013

PACKAGING INFORMATION

Orderable Device

TPS92560DGQ/NOPB

TPS92560DGQR/NOPB

Status Package Type Package Pins Package Qty

Eco Plan Lead/Ball Finish

MSL Peak Temp

Op Temp (°C)

-40 to 85

Top-Side Markings

Samples

Drawing

(1)

(2)

(3)

(4)

ACTIVE

MSOP-

PowerPAD

DGQ

1000

3500

Green (RoHS

& no Sb/Br)

CU SN

Level-3-260C-168 HR

SN3B

ACTIVE

MSOP-

DGQ

Green (RoHS

& no Sb/Br)

Level-3-260C-168 HR

-40 to 85

PowerPAD

⁽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.

⁽⁴⁾Only one of markings shown within the brackets will appear on the physical device.

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

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TPS92560DGQ/NOPB CAD模型

原理图符号

PCB 封装图

TPS92560DGQ/NOPB 替代型号

型号	制造商	描述	替代类型	文档
TPS92560DGQR/NOPB	TI	暂无描述	类似代替

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