TI TPS61165DRVT

TPS61165
www.ti.com
SLVS790 – NOVEMBER 2007
High Brightness White LED Driver in 2mm x 2mm
QFN Package
FEATURES
APPLICATIONS
The default white LED current is set with the external
sensor resistor Rset, and the feedback voltage is
regulated to 200mV, as shown in the typical
application. During the operation, the LED current can
be controlled using the 1 wire digital interface
(Easyscale™ protocol) through the CTRL pin.
Alternatively, a pulse width modulation (PWM) signal
can be applied to the CTRL pin through which the
duty cycle determines the feedback reference
voltage. In either digital or PWM mode, the
TPS61165 does not burst the LED current; therefore,
it does not generate audible noises on the output
capacitor. For maximum protection, the device
features integrated open LED protection that disables
the TPS61165 to prevent the output from exceeding
the absolute maximum ratings during open LED
conditions.
•
•
The TPS61165 is available in a space-saving,
2mm × 2mm QFN package with thermal pad.
1
•
•
•
•
•
•
•
•
3-V to 18-V Input Voltage Range
38-V Open LED Protection for 10 LEDs
200-mV Reference Voltage With 2% Accuracy
1.2-A Switch FET With 1.2-MHz Switching
Frequency
Flexible 1 Wire Digital and PWM Brightness
Control
Built-in Soft Start
Up to 90% Efficiency
2mm × 2mm × 0.8mm 6-pin QFN Package With
Thermal Pad
High Brightness LED Lighting
White LED Backlighting for Media Form Factor
Display
DESCRIPTION
With a 40-V rated integrated switch FET, the
TPS61165 is a boost converter that drives up to 10
LEDs in series. The boost converter runs at a
1.2-MHz fixed switching frequency with 1.2-A switch
current limit, and allows for the use of a high
brightness LED in general lighting.
L1
10 mH
VIN 5V
C1
4.7 mF
D1
TPS61165
ON/OFF
DIMMING
CONTROL
VIN
SW
CTRL
FB
COMP
GND
C2
1 mF
350 mA
220 nF
Rset
0.57 W
L 1 : TOKO #A 915 _Y-100M
C1 : Murata GRM 188R61A475 K
C2 : Murata GRM 188R61E105K
D1 : ONsemi MBR0540T1
LED : OSRAM LW-W 5SM
Figure 1. Typical Application
1
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.
Copyright © 2007, Texas Instruments Incorporated
TPS61165
www.ti.com
SLVS790 – NOVEMBER 2007
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 (1)
(1)
(2)
TA
OPEN LED PROTECTION
PACKAGE (2)
PACKAGE MARKING
–40°C to 85°C
38 V (typical)
TPS61165DRVR
CCQ
For the most current package and ordering information, see the TI Web site at www.ti.com.
The DRV package is available in tape and reel. Add R suffix (TPS61165DRVR) to order quantities of 3000 parts per reel or add T suffix
(TPS61165DRVT) to order 250 parts per reel.
ABSOLUTE MAXIMUM RATINGS
over operating free-air temperature range (unless otherwise noted)
Supply Voltages on VIN
VI
(1)
(2)
VALUE
UNIT
–0.3 to 20
V
Voltages on CTRL (2)
–0.3 to 20
V
Voltage on FB and COMP (2)
–0.3 to 3
V
–0.3 to 40
V
Voltage on SW
(2)
PD
Continuous Power Dissipation
TJ
Operating Junction Temperature Range
–40 to 150
°C
TSTG
Storage Temperature Range
–65 to 150
°C
(1)
(2)
See Dissipation Rating Table
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.
All voltage values are with respect to network ground terminal.
DISSIPATION RATINGS
DERATING FACTOR
ABOVE TA = 25°C
BOARD PACKAGE
RθJC
RθJA
Low-K (1)DRV
20°C/W
140°C/W
20°C/W
65°C/W
High-K
(1)
(2)
(2)
DRV
TA < 25°C
TA = 70°C
TA = 85°C
7.1 mW/°C
715 mW
395 mW
285 mW
15.4 mW/°C
1540 mW
845 mW
615 mW
The JEDEC low-K (1s) board used to derive this data was a 3in×3in, two-layer board with 2-ounce copper traces on top of the board.
The JEDEC high-K (2s2p) board used to derive this data was a 3in×3in, multilayer board with 1-ounce internal power and ground planes
and 2-ounce copper traces on top and bottom of the board.
RECOMMENDED OPERATING CONDITIONS
MIN
VI
Input voltage range, VIN
VO
Output voltage range
L
Inductor (1)
fdim
TYP
MAX
UNIT
3
18
VIN
38
V
10
22
µH
PWM dimming frequency
5
100
kHz
CIN
Input capacitor
1
CO
Output capacitor
1
10
µF
TA
Operating ambient temperature
–40
85
°C
TJ
Operating junction temperature
–40
125
°C
(1)
2
V
µF
These values are recommended values that have been successfully tested in several applications. Other values may be acceptable in
other applications but should be fully tested by the user.
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SLVS790 – NOVEMBER 2007
ELECTRICAL CHARACTERISTICS
VIN = 3.6 V, CTRL = VIN, TA = –40°C to 85°C, typical values are at TA = 25°C (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
SUPPLY CURRENT
VI
Input voltage range, VIN
3
IQ
Operating quiescent current into VIN
Device PWM switching no load
ISD
Shutdown current
CRTL=GND, VIN = 4.2 V
UVLO
Under-voltage lockout threshold
VIN falling
Vhys
Under-voltage lockout hysterisis
2.2
18
V
2.3
mA
1
µA
2.5
V
70
mV
ENABLE AND REFERENCE CONTROL
V(CTRLh)
CTRL logic high voltage
VIN = 3 V to 18 V
1.2
V
V(CTRLl)
CTRL logic low voltage
VIN = 3 V to 18 V
R(CTRL)
CTRL pull down resistor
toff
CTRL pulse width to shutdown
CTRL high to low
2.5
ms
tes_det
Easy Scale detection time (1)
CTRL pin low
260
µs
tes_delay
Easy Scale detection delay
tes_win
Easy Scale detection window time
0.4
400
Measured from CTRL high
800
1600
V
kΩ
100
µs
1
ms
VOLTAGE AND CURRENT CONTROL
VREF
Voltage feedback regulation voltage
196
200
204
mV
V(REF_PWM)
Voltage feedback regulation voltage under
brightness control
VFB = 50 mV
47
50
53
mV
VFB = 20 mV
17
20
23
IFB
Voltage feedback input bias current
VFB = 200 mV
fS
Oscillator frequency
1.0
1.2
1.5
Dmax
Maximum duty cycle
90%
93%
tmin_on
Minimum on pulse width
Isink
Isource
Gea
Error amplifier transconductance
Rea
Error amplifier output resistance
fea
Error amplifier crossover frequency
2
VFB = 100 mV
µA
MHz
40
ns
Comp pin sink current
100
µA
Comp pin source current
100
240
320
µA
400
umho
6
MΩ
5 pF connected to COMP
500
kHz
VIN = 3.6 V
0.3
POWER SWITCH
RDS(ON)
ILN_NFET
N-channel MOSFET on-resistance
VIN = 3.0 V
0.6
Ω
0.7
N-channel leakage current
VSW = 35 V, TA = 25°C
ILIM
N-Channel MOSFET current limit
D = Dmax
ILIM_Start
Start up current limit
D = Dmax
tHalf_LIM
Time step for half current limit
Vovp
Open LED protection threshold
Measured on the SW pin
Open LED protection threshold on FB
Measured on the FB pin, percentage of
Vref, Vref = 200 mV and 20 mV
1
µA
1.44
A
OC and OLP
V(FB_OVP)
tREF
VREF filter time constant
tstep
VREF ramp up time
(1)
0.96
1.2
0.7
A
5
Each step, Measured as number of
cycles of the 1.2 MHz clock
37
38
ms
39
V
50%
180
µs
213
µs
To select EasyScale™ mode, the CTRL pin has to be low for more than tes_det during tes_win.
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ELECTRICAL CHARACTERISTICS (continued)
VIN = 3.6 V, CTRL = VIN, TA = –40°C to 85°C, typical values are at TA = 25°C (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
EasyScale TIMING
µs
tstart
Start time of program stream
2
tEOS
End time of program stream
2
360
µs
tH_LB
High time low bit
Logic 0
2
180
µs
tL_LB
Low time low bit
Logic 0
2 × tH_LB
360
µs
tH_HB
High time high bit
Logic 1
2 × tL_HB
360
µs
tL_HB
Low time high bit
Logic 1
2
180
µs
VACKNL
Acknowledge output voltage low
Open drain, Rpullup =15 kΩ to VIN
tvalACKN
Acknowledge valid time
See
tACKN
Duration of acknowledge condition
See
0.4
V
(2)
2
µs
(2)
512
µs
THERMAL SHUTDOWN
Tshutdown
Thermal shutdown threshold
Thysteresis
Thermal shutdown threshold hysteresis
(2)
160
°C
15
°C
Acknowledge condition active 0, this condition will only be applied in case the RFA bit is set. Open drain output, line must be pulled high
by the host with resistor load.
DEVICE INFORMATION
TOP VIEW
FB
COMP
GND
VIN
Thermal
Pad
CTRL
SW
6-PIN 2mm x 2mm x 0.8mm QFN
TERMINAL FUNCTIONS
TERMINAL
NAME
NO.
I/O
DESCRIPTION
VIN
6
I
The input supply pin for the IC. Connect VIN to a supply voltage between 3V and 18V.
SW
4
I
This is the switching node of the IC. Connect the switched side of the inductor to SW. This pin is also used
to sense the output voltage for open LED protection.
GND
3
O
Ground
FB
1
I
Feedback pin for current. Connect the sense resistor from FB to GND.
COMP
2
O
Output of the transconductance error amplifier. Connect an external capacitor to this pin to compensate the
regulator.
CTRL
5
I
Control pin of the boost regulator. It is a multi-functional pin which can be used for enable control, PWM
and digital dimming.
Thermal Pad
4
The thermal pad should be soldered to the analog ground plane. If possible, use thermal via to connect to
ground plane for ideal power dissipation.
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FUNCTIONAL BLOCK DIAGRAM
C2
D1
1
Rset
4
FB
L1
SW
Reference
Control
Error
Amplifer
OLP
Vin
6
COMP
2
C1
PWM Control
C3
5
Soft
Start-up
CTRL
Ramp
Generator
+
Current
Sensor
Oscillator
GND
3
TYPICAL CHARACTERISTICS
TABLE OF GRAPHS
FIGURE
Efficiency
3 LEDs (VOUT = 12V); VIN = 3, 5, 8.5V; L = 10 µH
Figure 2
Efficiency
6 LEDs (VOUT = 24V); VIN = 5, 8.5, 12V; L = 10 µH
Figure 3
Current limit
TA = 25°C
Figure 4
Current limit
Figure 5
Easyscale step
Figure 6
PWM dimming linearity
VIN = 3.6 V; PWM Freq = 10 kHz and 32 kHz
Figure 7
Output ripple at PWM dimming
3 LEDs; VIN = 5 V; ILOAD = 350 mA; PWM 32 kHz
Figure 8
Switching waveform
3 LEDs; VIN = 5 V; ILOAD = 3500 mA; L = 10 µH
Figure 9
Start-up
3 LEDs; VIN = 5 V; ILOAD = 350 mA; L = 10 µH
Figure 10
Open LED protection
8 LEDs; VIN = 3.6 V; ILOAD = 20 mA
Figure 11
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EFFICIENCY
vs
OUTPUT CURRENT
EFFICIENCY
vs
OUTPUT CURRENT
100
100
VIN = 8.5 V
3 LEDs ( VOUT = 12 V )
VIN = 12 V
6 LEDs ( VOUT = 24 V )
90
90
VIN = 8.5 V
VIN = 5 V
VIN = 5 V
VIN = 3 V
Efficiency - %
Efficiency - %
80
70
70
60
60
50
50
40
40
0
50
100
150
200
Output Current - mA
250
0
300
100
150
200
Output Current - mA
250
Figure 3.
SWITCH CURRENT LIMIT
vs
DUTY CYCLE
SWITCH CURRENT LIMIT
vs
TEMPERATURE
1600
1600
1500
1500
1400
1400
1300
1200
1100
1000
900
300
1300
1200
1100
1000
900
800
20
30
40
50
60
Duty Cycle - %
70
80
800
-40
90
-20
0
20
40
60
80
Temperature - °C
Figure 4.
Figure 5.
FB VOLTAGE
vs
EASYSCALE STEP
FB VOLTAGE
vs
PWM DUTY CYCLE
200
100
120
140
200
PWM 10 kHz, 32 kHz
180
160
160
FB Voltage - mV
140
FB Voltage - mV
50
Figure 2.
Switch Current Limit - mA
Switch Current Limit - A
80
120
100
80
120
80
60
40
40
20
0
0
0
2
4
6
8
10 12 14 16 18 20 22 24 26 28 30 32
Easy Scale Step
0
Figure 6.
6
20
40
60
PWM Duty Cycle - %
80
100
Figure 7.
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OUTPUT RIPPLE at PWM DIMMING
PWM 5 V/div
SWITCHING WAVEFORM
SW 5 V/div
VOUT 50 mV/div AC
VOUT 200 mV/div AC
IL 500 mA/div
ILED 200 mA/div
t - 20 ms/div
t - 400 ns/div
Figure 8.
Figure 9.
START-UP
OPEN LED PROTECTION
CTRL 5 V/div
OPEN LED 5 V/div
FB 200 mV/div
VOUT 5 V/div
VOUT 10 V/div
IL 200 mA/div
COMP 500 mV/div
IL 500 mA/div
t - 100 ms/div
t - 2 ms/div
Figure 10.
Figure 11.
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DETAILED DESCRIPTION
OPERATION
The TPS61165 is a high efficiency, high output voltage boost converter in small package size, The device is ideal
for driving up to 10 white LED in series. The serial LED connection provides even illumination by sourcing the
same output current through all LEDs, eliminating the need for expensive factory calibration. The device
integrates 40V/1.2A switch FET and operates in pulse width modulation (PWM) with 1.2MHz fixed switching
frequency. For operation see the block diagram. The duty cycle of the converter is set by the error amplifier
output and the current signal applied to the PWM control comparator. The control architecture is based on
traditional current-mode control; therefore, a slope compensation is added to the current signal to allow stable
operation for duty cycles larger than 40%. The feedback loop regulates the FB pin to a low reference voltage
(200mV typical), reducing the power dissipation in the current sense resistor.
SOFT START-UP
Soft-start circuitry is integrated into the IC to avoid a high inrush current during start-up. After the device is
enabled, the voltage at FB pin ramps up to the reference voltage in 32 steps, each step takes 213µs. This
ensures that the output voltage rises slowly to reduce the input current. Additionally, for the first 5msec after the
COMP voltage ramps, the current limit of the switch is set to half of the normal current limit spec. During this
period, the input current is kept below 700mA (typical). These two features ensure smooth start-up and minimize
the inrush current. See the start-up waveform of a typical example (Figure 10).
OPEN LED PROTECTION
Open LED protection circuitry prevents IC damage as the result of white LED disconnection. The TPS61165
monitors the voltage at the SW pin and FB pin during each switching cycle. The circuitry turns off the switch FET
and shuts down the IC as soon as the SW voltage exceeds the Vovp threshold, and the FB voltage is less than
half of regulation voltage for 8 clock cycles. As a result, the output voltage falls to the level of the input supply.
The device remains in shutdown mode until it is enabled by toggling the CTRL pin logic. To allow the use of
inexpensive low-voltage output capacitor, the TPS61165 has different open lamp protection thresholds to prevent
the internal 40V FET from breaking down. The threshold is set at 38V.
SHUTDOWN
The TPS61165 enters shutdown mode when the CTRL voltage is logic low for more than 2.5ms. During
shutdown, the input supply current for the device is less than 1µA (max). Although the internal FET does not
switch in shutdown, there is still a DC current path between the input and the LEDs through the inductor and
Schottky diode. The minimum forward voltage of the LED array must exceed the maximum input voltage to
ensure that the LEDs remain off in shutdown.
CURRENT PROGRAM
The FB voltage is regulated by a low 0.2V reference voltage. The LED current is programmed externally using a
current-sense resistor in series with the LED string. The value of the RSET is calculated using Equation 1 .
V
I LED + FB
RSET
(1)
Where:
ILED = output current of LEDs
VFB = regulated voltage of FB
RSET = current sense resistor
The output current tolerance depends on the FB accuracy and the current sensor resistor accuracy.
8
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LED BRIGTHNESS DIMMING MODE SELECTION
The CTRL pin is used for the control input for both dimming modes, PWM dimming and the 1 wire dimming. The
dimming mode for the TPS61165 is selected each time the device is enabled. The default dimming mode is
PWM dimming. To enter 1 wire mode, the following digital pattern on the CTRL pin must be recognized by the IC
every time the IC starts from the shutdown mode.
1. Pull CTRL pin high to enable the TPS61165, and to start the 1 wire detection window.
2. After the EasyScale detection delay (tes_delay, 100µs) expires, drive CTRL low for more than the EasyScale
detection time (tes_detect, 260µs).
3. The CTRL pin has to be low for more than EasyScale detection time before the EasyScale detection window
(tes_win, 1msec) expires. EasyScale detection window starts from the first CTRL pin low to high transition.
The IC immediately enters the 1 wire mode once the above 3 conditions are met. the EasyScale communication
can start before the detection window expires. Once the dimming mode is programmed, it can not be changed
without another start up. This means the IC needs to be shutdown by pulling the CTRL low for 2.5ms and
restarts. See the Dimming Mode Detection and Soft Start (see Figure 12) for a graphical explanation.
Insert battery
PWM signal
high
CTRL
low
PWM
mode
Startup
delay
FB ramp
Shutdown delay
200mV x duty cycle
FB
t
Insert battery
Enter ES mode
Enter ES mode
Timing window
Programming
code
Programming code
high
CTRL
low
ES detect time
ES
mode
ES detect delay
Shutdown
delay
IC
Shutdown
Programmed value
(if not programmed, 200mV default )
FB
FB ramp
FB ramp
Startup delay
50mV
Startup delay
50mV
Figure 12. Dimming Mode Detection and Soft Start PWM Brightness Dimming
PWM BRIGHTNESS DIMMING
When the CTRL pin is constantly high, the FB voltage is regulated to 200mV typically. However, the CTRL pin
allows a PWM signal to reduce this regulation voltage; therefore, it achieves LED brightness dimming. The
relationship between the duty cycle and FB voltage is given by Equation 2:
V FB + Duty 200 mV
(2)
Where:
Duty = duty cycle of the PWM signal
200 mV = internal reference voltage
As shown in Figure 13, the IC chops up the internal 200mV reference voltage at the duty cycle of the PWM
signal. The pulse signal is then filtered by an internal low pass filter. The output of the filter is connected to the
error amplifier as the reference voltage for the FB pin regulation. Therefore, although a PWM signal is used for
brightness dimming, only the WLED DC current is modulated, which is often referred as analog dimming. This
eliminates the audible noise which often occurs when the LED current is pulsed in replica of the frequency and
duty cycle of PWM control. Unlike other scheme which filters the PWM signal for analog dimming, TPS61165
regulation voltage is independent of the PWM logic voltage level which often has large variations.
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For optimum performance, use the PWM dimming frequency in the range of 5kHz to 100kHz. The requirement of
minimum dimming frequency comes from the EasyScale detection delay and detection time specification in the
dimming mode selection. Since the CTRL pin is logic only pin, adding external RC filter applied to the pin does
not work.
To use lower PWM dimming, add external RC network connected to the FB pin as shown in the additional typical
application, Figure 17.
VBG
200 mV
CTRL
FB
Error
Amplifer
Figure 13. Block Diagram of Programmable FB Voltage Using PWM Signal
DIGITAL 1 WIRE BRIGHTNESS DIMMING
The CTRL pin features a simple digital interface to allow digital brightness control. The digital dimming can save
the processor power and battery life as it does not require a PWM signal all the time, and the processor can
enter idle mode if available.
The TPS61165 adopts the EasyScale™ protocol for the digital dimming, which can program the FB voltage to
any of the 32 steps with single command. The step increment increases with the voltage to produce pseudo
logarithmic curve for the brightness step. See Table 1 for the FB pin voltage steps. The default step is full scale
when the device is first enabled (VFB = 200 mV). The programmed reference voltage is stored in an internal
register. A power reset clears the register value and reset it to default.
EasyScale™: 1 WIRE DIGITAL DIMMING
EasyScale is a simple but flexible one pin interface to configure the FB voltage. The interface is based on a
master-slave structure, where the master is typically a microcontroller or application processor. Figure 14 and
Table 2 give an overview of the protocol. The protocol consists of a device specific address byte and a data byte.
The device specific address byte is fixed to 72 hex. The data byte consists of five bits for information, two
address bits, and the RFA bit. The RFA bit set to high indicates the Request for Acknowledge condition. The
Acknowledge condition is only applied if the protocol was received correctly. The advantage of EasyScale
compared with other on pin interfaces is that its bit detection is in a large extent independent from the bit
transmission rate. It can automatically detect bit rates between 1.7kBit/sec and up to 160kBit/sec.
Table 1. Selectable FB Voltage
10
FB voltage
(mV)
D4
D3
D2
D1
D0
0
0
0
0
0
0
0
1
5
0
0
0
0
1
2
8
0
0
0
1
0
3
11
0
0
0
1
1
4
14
0
0
1
0
0
5
17
0
0
1
0
1
6
20
0
0
1
1
0
7
23
0
0
1
1
1
8
26
0
1
0
0
0
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Table 1. Selectable FB Voltage (continued)
FB voltage
(mV)
D4
D3
D2
D1
D0
9
29
0
1
0
0
1
10
32
0
1
0
1
0
11
35
0
1
0
1
1
12
38
0
1
1
0
0
13
44
0
1
1
0
1
14
50
0
1
1
1
0
15
56
0
1
1
1
1
16
62
1
0
0
0
0
17
68
1
0
0
0
1
18
74
1
0
0
1
0
19
80
1
0
0
1
1
20
86
1
0
1
0
0
21
92
1
0
1
0
1
22
98
1
0
1
1
0
23
104
1
0
1
1
1
24
116
1
1
0
0
0
25
128
1
1
0
0
1
26
140
1
1
0
1
0
27
152
1
1
0
1
1
28
164
1
1
1
0
0
29
176
1
1
1
0
1
30
188
1
1
1
1
0
31
200
1
1
1
1
1
DATA IN
DATABYTE
Device Address
Start
Start DA7 DA6 DA5 DA4 DA3 DA2 DA1
0
1
1
1
0
0
1
DA0 EOS Start RFA
0
A1
A0
D4
D3
D2
D1
D0
EOS
DATA OUT
ACK
Figure 14. EasyScale™ Protocol Overview
Table 2. EasyScale™ Bit Description
BYTE
Device
Address
Byte
72 hex
BIT
NUMBER
NAME
TRANSMISSION
DIRECTION
7
DA7
0 MSB device address
6
DA6
1
5
DA5
1
4
DA4
3
DA3
2
DA2
0
1
DA1
1
0
DA0
0 LSB device address
IN
DESCRIPTION
1
0
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Table 2. EasyScale™ Bit Description (continued)
BYTE
Data byte
BIT
NUMBER
TRANSMISSION
DIRECTION
NAME
7 (MSB)
RFA
6
A1
0 Address bit 1
5
A0
0 Address bit 0
4
D4
3
D3
2
D2
Data bit 2
1
D1
Data bit 1
0 (LSB)
D0
Data bit 0
DESCRIPTION
Request for acknowledge. If high, acknowledge is applied by device
Data bit 4
IN
ACK
Data bit 3
Acknowledge condition active 0, this condition will only be applied in case RFA bit is
set. Open drain output, Line needs to be pulled high by the host with a pullup
resistor. This feature can only be used if the master has an open drain output stage.
In case of a push pull output stage Acknowledge condition may not be requested!
OUT
Easy Scale Timing, without acknowledge RFA = 0
t Start
DATA IN
t Start
Address Byte
DATA Byte
Static High
Static High
DA7
0
DA0
0
D0
1
RFA
0
TEOS
TEOS
Easy Scale Timing, with acknowledge RFA = 1
t Start
DATA IN
t Start
Address Byte
DATA Byte
Static High
Static High
DA7
0
DA0
0
TEOS
RFA
1
D0
1
Controller needs to
Pullup Data Line via a
resistor to detect ACKN
DATA OUT
tLow
Low Bit
(Logic 0)
t High
tLOW
t valACK
ACKN
t ACKN
Acknowledge
true, Data Line
pulled down by
device
Acknowledge
false, no pull
down
tHigh
High Bit
(Logic 1)
Figure 15. EasyScale™— Bit Coding
12
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All bits are transmitted MSB first and LSB last. Figure 15 shows the protocol without acknowledge request (Bit
RFA = 0), Figure 15 with acknowledge (Bit RFA = 1) request. Prior to both bytes, device address byte and data
byte, a start condition must be applied. For this, the CTRL pin must be pulled high for at least tstart (2µs) before
the bit transmission starts with the falling edge. If the CTRL pin is already at a high level, no start condition is
needed prior to the device address byte. The transmission of each byte is closed with an End of Stream
condition for at least tEOS (2µs).
The bit detection is based on a Logic Detection scheme, where the criterion is the relation between tLOW and
tHIGH. It can be simplified to:
High Bit: tHIGH > tLOW, but with tHIGH at least 2x tLOW, see Figure 15.
Low Bit: tHIGH < tLOW, but with tLOW at least 2x tHIGH, see Figure 15.
The bit detection starts with a falling edge on the CTRL pin and ends with the next falling edge. Depending on
the relation between tHIGH and tLOW, the logic 0 or 1 is detected.
The acknowledge condition is only applied if:
• Acknowledge is requested by a set RFA bit.
• The transmitted device address matches with the device address of the device.
• 16 bits is received correctly.
If the device turns on the internal ACKN-MOSFET and pulls the CTRL pin low for the time tACKN, which is 512µs
maximum then the Acknowledge condition is valid after an internal delay time tvalACK. This means that the internal
ACKN-MOSFET is turned on after tvalACK, when the last falling edge of the protocol was detected. The master
controller keeps the line low in this period. The master device can detect the acknowledge condition with its input
by releasing the CTRL pin after tvalACK and read back a logic 0. The CTRL pin can be used again after the
acknowledge condition ends.
Note that the acknowledge condition may only be requested if the master device has an open drain output. For a
push-pull output stage, the use a series resistor in the CRTL line to limit the current to 500µA is recommended to
for such cases as:
• accidentally requested acknowledge, or
• to protect the internal ACKN-MOSFET.
UNDERVOLTAGE LOCKOUT
An undervoltage lockout prevents operation of the device at input voltages below typical 2.2V. When the input
voltage is below the undervoltage threshold, the device is shutdown and the internal switch FET is turned off. If
the input voltage rises by undervoltage lockout hysteresis, the IC restarts.
THERMAL SHUTDOWN
An internal thermal shutdown turns off the device when the typical junction temperature of 160°C is exceeded.
The device is released from shutdown automatically when the junction temperature decreases by 15°C.
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APPLICATION INFORMATION
MAXIMUM OUTPUT CURRENT
The overcurrent limit in a boost converter limits the maximum input current and thus maximum input power for a
given input voltage. Maximum output power is less than maximum input power due to power conversion losses.
Therefore, the current limit setting, input voltage, output voltage and efficiency can all change maximum current
output. The current limit clamps the peak inductor current; therefore, the ripple has to be subtracted to derive
maximum DC current. The ripple current is a function of switching frequency, inductor value and duty cycle. The
following equations take into account of all the above factors for maximum output current calculation.
1
IP =
é
1
1 ù
+
)ú
êL ´ Fs ´ (
Vout + Vf - Vin Vin û
ë
(3)
Where:
Ip = inductor peak to peak ripple
L = inductor value
Vf = Schottky diode forward voltage
Fs = switching frequency
Vout = output voltage of the boost converter. It is equal to the sum of VFB and the voltage drop across LEDs.
I out_max +
Vin
ǒI lim * I Pń2Ǔ
h
Vout
(4)
where
Iout_max = Maximum output current of the boost converter
Ilim = over current limit
η = efficiency
For instance, when VIN is 3.0V, 8 LEDs output equivalent to VOUT of 26V, the inductor is 22µH, the Schottky
forward voltage is 0.2V; and then the maximum output current is 65mA in typical condition. When VIN is 5V, 10
LEDs output equivalent to VOUT of 32V, the inductor is 22µH, the Schottky forward voltage is 0.2V; and then the
maximum output current is 85mA in typical condition.
INDUCTOR SELECTION
The selection of the inductor affects steady state operation as well as transient behavior and loop stability. These
factors make it the most important component in power regulator design. There are three important inductor
specifications, inductor value, DC resistance and saturation current. Considering inductor value alone is not
enough.
The inductor value determines the inductor ripple current. Choose an inductor that can handle the necessary
peak current without saturating, according to half of the peak-to-peak ripple current given by Equation 3, pause
the inductor DC current given by:
I in_DC + Vout Iout
Vin h
(5)
Inductor values can have ±20% tolerance with no current bias. When the inductor current approaches saturation
level, its inductance can decrease 20% to 35% from the 0A value depending on how the inductor vendor defines
saturation current. Using an inductor with a smaller inductance value forces discontinuous PWM when the
inductor current ramps down to zero before the end of each switching cycle. This reduces the boost converter’s
maximum output current, causes large input voltage ripple and reduces efficiency. Large inductance value
provides much more output current and higher conversion efficiency. For these reasons, a 10µH to 22µH
inductor value range is recommended. A 22µH inductor optimized the efficiency for most application while
maintaining low inductor peak to peak ripple. Table 3 lists the recommended inductor for the TPS61165. When
recommending inductor value, the factory has considered –40% and +20% tolerance from its nominal value.
14
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TPS61165 has built-in slope compensation to avoid sub-harmonic oscillation associated with current mode
control. If the inductor value is lower than 10µH, the slope compensation may not be adequate, and the loop can
be unstable. Therefore, customers need to verify the inductor in their application if it is different from the
recommended values.
Table 3. Recommended Inductors for TPS61165
PART NUMBER
L
(µH)
DCR MAX
(mΩ)
SATURATION CURRENT
(A)
SIZE
(L × W × H mm)
VENDOR
A915_Y-100M
10
90
1.3
5.2×5.2×3.0
TOKO
VLCF5020T-100M1R1-1
10
237
1.1
5×5×2.0
TDK
CDRH4D22/HP
10
144
1.2
5×5×2.4
Sumida
LQH43PN100MR0
10
247
0.84
4.5×3.2×2.0
Murata
SCHOTTKY DIODE SELECTION
The high switching frequency of the TPS61165 demands a high-speed rectification for optimum efficiency.
Ensure that the diode’s average and peak current rating exceeds the average output current and peak inductor
current. In addition, the diode’s reverse breakdown voltage must exceed the open LED protection voltage. The
ONSemi MBR0540 and the ZETEX ZHCS400 are recommended for TPS61165.
COMPENSATION CAPACITOR SELECTION
The compensation capacitor C3 (see the block diagram), connected from COMP pin to GND, is used to stabilize
the feedback loop of the TPS61165. Use 220nF ceramic capacitor for C3.
INPUT AND OUTPUT CAPACITOR SELECTION
The output capacitor is mainly selected to meet the requirements for the output ripple and loop stability. This
ripple voltage is related to the capacitor’s capacitance and its equivalent series resistance (ESR). Assuming a
capacitor with zero ESR, the minimum capacitance needed for a given ripple can be calculated by:
ǒV out * V inǓ Iout
C out +
Vout Fs V ripple
(6)
where, Vripple = peak-to-peak output ripple. The additional output ripple component caused by ESR is calculated
using:
V ripple_ESR + I out RESR
Due to its low ESR, Vripple_ESR can be neglected for ceramic capacitors, but must be considered if tantalum or
electrolytic capacitors are used.
Care must be taken when evaluating a ceramic capacitors derating under dc bias, aging and AC signal. For
example, larger form factor capacitors (in 1206 size) have a self resonant frequencies in the range of the
switching frequency. So the effective capacitance is significantly lower. The DC bias can also significantly reduce
capacitance. Ceramic capacitors can loss as much as 50% of its capacitance at its rated voltage. Therefore,
leave the margin on the voltage rating to ensure adequate capacitance at the required output voltage.
The capacitor in the range of 1µF to 4.7µF is recommended for input side. The output requires a capacitor in the
range of 1µF to 10µF. The output capacitor affects the loop stability of the boost regulator. If the output capacitor
is below the range, the boost regulator can potentially become unstable.
The popular vendors for high value ceramic capacitors are:
TDK (http://www.component.tdk.com/components.php)
Murata (http://www.murata.com/cap/index.html)
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LAYOUT CONSIDERATIONS
As for all switching power supplies, especially those high frequency and high current ones, layout is an important
design step. If layout is not carefully done, the regulator could suffer from instability as well as noise problems.
To reduce switching losses, the SW pin rise and fall times are made as short as possible. To prevent radiation of
high frequency resonance problems, proper layout of the high frequency switching path is essential. Minimize the
length and area of all traces connected to the SW pin and always use a ground plane under the switching
regulator to minimize inter-plane coupling. The loop including the PWM switch, Schottky diode, and output
capacitor, contains high current rising and falling in nanosecond and should be kept as short as possible. The
input capacitor needs not only to be close to the VIN pin, but also to the GND pin in order to reduce the IC
supply ripple. Figure 16 shows a sample layout.
C1
Rset
Vin
LEDs Out
Vin
FB
L1
CTRL
COMP
CTRL
GND
SW
C3
C2
GND
Place enough
VIAs around
thermal pad to
enhance thermal
performance
LEDs IN
Minimize the
area of this
trace
Figure 16. Layout Recommendation
THERMAL CONSIDERATIONS
The maximum IC junction temperature should be restricted to 125°C under normal operating conditions. This
restriction limits the power dissipation of the TPS61165. Calculate the maximum allowable dissipation, PD(max),
and keep the actual dissipation less than or equal to PD(max). The maximum-power-dissipation limit is determined
using Equation 7:
P D(max) +
125°C * T A
RqJA
(7)
where, TA is the maximum ambient temperature for the application. RθJA is the thermal resistance
junction-to-ambient given in Power Dissipation Table.
The TPS61165 comes in a thermally enhanced QFN package. This package includes a thermal pad that
improves the thermal capabilities of the package. The RθJA of the QFN package greatly depends on the PCB
layout and thermal pad connection. The thermal pad must be soldered to the analog ground on the PCB. Using
thermal vias underneath the thermal pad as illustrated in the layout example. Also see the QFN/SON PCB
Attachment application report (SLUA271).
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ADDITIONAL TYPICAL APPLICATIONS
L1
10 mH
VIN 5V
D1
C2
1 mF
C1
4.7 mF
TPS 61165
VIN
ON/OFF
SW
CTRL
FB
10 kW
GND
COMP
80 kW
C3
220 nF
Rset
0.64 W
100 kW
L 1 : TOKO #A 915 _Y-100M
C1 : Murata GRM188R61A475K
C2 : Murata GRM188R61E105K
D1 : ONsemi MBR 0540 T1
LED : OSRAM LW -W 5SM
0.1 mF
PWM Signal: 1.8V ; 200 Hz
LED current =1.8V x (1-d) / (8x Rset)
Figure 17. Drive 3 High Brightness LEDs With External PWM Dimming Network
L1
10 mH
VIN 3 V to 6 V
D1
3s9p
27LEDs
C1
4.7 mF
C2
1 mF
TPS61165
VIN
ON /OFF
DIMMING
CONTROL
SW
CTRL
FB
COMP
GND
C3
220 nF
L1:
C1:
C2:
D1:
Rset
1.1 W
TOKO # A915_ Y-100 M
Murata GRM188 R61A475 K
Murata GRM188 R61E105 K
ONsemi MBR0540T 1
Figure 18. Drive 27 LEDs for Media Form Factor Display
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L1
10 mH
VIN 12 V
C1
4.7 mF
D1
C2
1 mF
TPS 61165
ON/OFF
DIMMING
CONTROL
VIN
SW
CTRL
FB
COMP
GND
350 mA
C3
220 nF
Rset
0.57 W
L1: TOKO #A915_Y-100M
C1: Murata GRM188R61A475K
C2: Murata GRM188R61E105K
D1: ONsemi MBR0540T1
LED: OSRAM LW-W5SM
Figure 19. Drive 6 High Brightness LEDs
C1
4.7 mF
C4
1 mF
L1
10 mH
VIN 9V to 15V
L2
10 mH
TPS 61165
VIN
ON/OFF
DIMMING
CONTROL
VOUT= 12 V
D1
C2
1 mF
SW
180 mA
CTRL
FB
COMP
GND
C3
220 nF
Rset
1.1 W
L1, L2: TOKO #A915_Y-100M
C1: Murata GRM188 R61A475K
C2: Murata GRM188 R61E105K
C4: Murata GRM188 R61H105K
D1: ONsemi MBR0540T1
*L1,L2 can be replaced by 1:1 transformer
Figure 20. Drive 4 High Brightness LED With SEPIC Topology
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PACKAGE OPTION ADDENDUM
www.ti.com
19-Nov-2007
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
TPS61165DRVR
ACTIVE
SON
DRV
6
3000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-1-260C-UNLIM
TPS61165DRVT
ACTIVE
SON
DRV
6
250
CU NIPDAU
Level-1-260C-UNLIM
Green (RoHS &
no Sb/Br)
Lead/Ball Finish
MSL Peak Temp (3)
(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.
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Addendum-Page 1
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