TI TLC59401RHBR

TLC59401
www.ti.com
SBVS137 – DECEMBER 2009
16-CHANNEL LED DRIVER WITH DOT CORRECTION AND GRAYSCALE PWM CONTROL
Check for Samples: TLC59401
FEATURES
APPLICATIONS
•
•
•
•
•
•
1
23
•
•
•
•
•
•
•
•
16 Channels
12-Bit (4096 Steps) Grayscale PWM Control
Dot Correction
– 6-Bit (64 Steps)
Drive Capability (Constant-Current Sink)
– 0 mA to 80 mA (VCC ≤ 3.6 V)
– 0 mA to 120 mA (VCC > 3.6 V)
LED Power-Supply Voltage up to 17 V
VCC = 3.0 V to 5.5 V
Serial Data Interface
Controlled Inrush Current
30-MHz Data Transfer Rate
CMOS Level I/O
Error Information
– LOD: LED Open Detection
– TEF: Thermal Error Flag
VCC
GND
SCLK
Monocolor, Multicolor, Full-Color LED Displays
LED Signboards
Display Back-Lighting
DESCRIPTION
The TLC59401 is a 16-channel, constant-current sink,
LED driver. Each channel has an individually
adjustable 4096-step grayscale PWM brightness
control and a 64-step constant-current sink (dot
correction). The dot correction adjusts the brightness
variations between LED channels and other LED
drivers. Both grayscale control and dot correction are
accessible via a serial interface. A single external
resistor sets the maximum current value of all 16
channels.
The TLC59401 features two error information circuits.
The LED open detection (LOD) indicates a broken or
disconnected LED at an output terminal. The thermal
error flag (TEF) indicates an over-temperature
condition.
XLAT
SIN
CNT
MODE
1 0
IREF
Max. OUTn
Current
V REF
=1.24V
GS Register
MODE
1 0
11
0
GSCLK
BLANK
0
DC Register
5
GS Counter
0
Status
Information:
LOD,
TED,
DC DATA
191
0
CNT
96
12−Bit Grayscale
PWM Control
Constant-Current
Driver
OUT0
Delay
x0
6−Bit Dot Correction
LED Open Detection
Input
Shift
Register
CNT
192
192
GS Register
23
96
95
1 0
96
12
DC Register
11
12−Bit Grayscale
PWM Control
Constant-Current
Driver
OUT1
Delay
x1
6−Bit Dot Correction
6
MODE
LED Open Detection
96
Temperature
Error Flag
(TEF)
LED Open
Detection
(LOD)
CNT
Input
Shift
Register
GS Register
191
XERR
180
DC Register
95
12−Bit Grayscale
PWM Control
Constant-Current
Driver
OUT15
Delay
x15
6−Bit Dot Correction
90
191
LED Open Detection
SOUT
Figure 1. Functional Block Diagram
1
2
3
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.
PowerPAD is a trademark of Texas Instruments Incorporated.
All other trademarks are the property of their respective owners.
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 © 2009, Texas Instruments Incorporated
TLC59401
SBVS137 – DECEMBER 2009
www.ti.com
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
ORDERING INFORMATION (1)
(1)
TA
PACKAGE
PART NUMBER
–40°C to +85°C
28-pin HTSSOP PowerPAD™
TLC59401PWP
–40°C to +85°C
32-pin 5 mm x 5 mm QFN
TLC59401RHB
For the most current package and ordering information, see the Package Option Addendum at the end
of this document, or see the TI web site at www.ti.com.
ABSOLUTE MAXIMUM RATINGS (1)
Over operating free-air temperature range, unless otherwise noted.
TLC59401
VI
Input voltage range (2)
IO
Output current (dc)
VI
Input voltage range
VO
Output voltage range
ESD rating
VCC
UNIT
–0.3 to 6
V
130
mA
V(BLANK), V(SCLK), V(XLAT), V(MODE), V(SIN), V(GSCLK), V(IREF),
V(TEST)
–0.3 to VCC +0.3
V
V(SOUT), V(XERR)
–0.3 to VCC +0.3
V
V(OUT0) to V(OUT15)
HBM (JEDEC JESD22-A114, human body model)
CDM (JEDEC JESD22-C101, charged device model)
TJ(max) Operating junction temperature
–0.3 to 18
V
2
kV
500
V
+150
°C
°C
TSTG
Storage temperature range
–55 to +150
TA
Operating ambient temperature range
–40 to +85
°C
HTSSOP (PWP) (4)
31.58
°C/W
QFN (RHB) (4)
35.9
°C/W
Package thermal impedance (3)
(1)
(2)
(3)
(4)
2
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.
The package thermal impedance is calculated in accordance with JESD 51-7.
With PowerPAD soldered on PCB with 2-oz. trace of copper. See TI application report SLMA002 for further information.
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SBVS137 – DECEMBER 2009
RECOMMENDED OPERATING CONDITIONS
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
DC CHARACTERISTICS
VCC
Supply Voltage
3
5.5
V
VO
Voltage applied to output (OUT0 – OUT15)
VIH
17
V
High-level input voltage
0.8 VCC
VCC
V
VIL
Low-level input voltage
GND
0.2 VCC
V
IOH
High-level output current
VCC = 5 V at SOUT
IOL
Low-level output current
VCC = 5 V at SOUT, XERR
OUT0 to OUT15, VCC ≤ 3.6 V
–1
mA
1
mA
80
mA
IOLC
Constant output current
120
mA
TJ
Operating junction temperature
–40
+125
°C
TA
Operating free-air temperature range
–40
+85
°C
OUT0 to OUT15, VCC > 3.6 V
AC CHARACTERISTICS
At VCC = 3 V to 5.5 V and TA = –40°C to +85°C, unless otherwise noted.
f(SCLK)
Data shift clock
frequency
SCLK
30
MHz
f(GSCLK)
Grayscale clock
frequency
GSCLK
30
MHz
twh0/twl0
SCLK pulse duration
SCLK = high/low (see Figure 12)
16
ns
twh1/twl1
GSCLK pulse duration
GSCLK = high/low (see Figure 12)
16
ns
twh2
XLAT pulse duration
XLAT = high (see Figure 12)
20
ns
twh3
BLANK pulse duration
BLANK = high (see Figure 12)
20
ns
tsu0
SIN - SCLK↑ (see Figure 12)
tsu1
SCLK↓ - XLAT↑ (see Figure 12)
10
tsu2
MODE↑↓ - SCLK↑ (see Figure 12)
10
MODE↑↓ - XLAT↑ (see Figure 12)
10
tsu4
BLANK↓ - GSCLK↑ (see Figure 12)
10
tsu5
XLAT↑ - GSCLK↑ (see Figure 12)
30
th0
SCLK↑ - SIN (see Figure 12)
th1
XLAT↓ - SCLK↑ (see Figure 12)
10
tsu3
th2
Setup time
Hold Time
5
ns
3
SCLK↑ - MODE↑↓ (see Figure 12)
10
th3
XLAT↓ - MODE↑↓ (see Figure 12)
10
th4
GSCLK↑ - BLANK↑ (see Figure 12)
10
ns
DISSIPATION RATINGS
(1)
PACKAGE
POWER RATING
TA < +25°C
DERATING FACTOR
ABOVE TA = +25°C
POWER RATING
TA = +70°C
POWER RATING
TA = +85°C
28-pin HTSSOP with
PowerPAD soldered (1)
3958 mW
31.67 mW/°C
2533 mW
2058 mW
28-pin HTSSOP
without PowerPAD
soldered
2026 mW
16.21 mW/°C
1296 mW
1053 mW
32-pin QFN (1)
3482 mW
27.86 mW/°C
2228 mW
1811 mW
The PowerPAD is soldered to the PCB with a 2-oz. copper trace. See application report SLMA002 for further information.
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TLC59401
SBVS137 – DECEMBER 2009
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ELECTRICAL CHARACTERISTICS
At VCC = 3 V to 5.5 V and TA = –40°C to +85°C, unless otherwise noted.
TLC59401
PARAMETER
TEST CONDITIONS
VOH
High-level output voltage
IOH = –1 mA, SOUT
VOL
Low-level output voltage
IOL = 1 mA, SOUT
II
Input current
MIN
TYP
VI = VCC or GND; BLANK, TEST, GSCLK, SCLK, SIN, XLAT pin
–1
VI = GND; MODE pin
–1
Supply current
V
1
μA
1
μA
50
μA
0.9
6
mA
No data transfer, all output OFF, VO = 1 V, R(IREF) = 1.3 kΩ
5.2
12
mA
Data transfer 30 MHz, all output ON, VO = 1 V, R(IREF) = 1.3 kΩ
16
25
mA
Data transfer 30 MHz, all output ON, VO = 1 V, R(IREF) = 640 Ω
30
60
mA
61
69
mA
0.1
μA
±1
±4
%
Constant output current
All output ON, VO = 1 V, R(IREF) = 640 Ω
Ilkg
Leakage output current
All output OFF, VO = 15 V, R(IREF) = 640 Ω , OUT0 to OUT15
54
All output ON, VO = 1 V, R(IREF) = 640 Ω, OUT0 to OUT15,
–20°C to +85°C (1)
All output ON, VO = 1 V, R(IREF) = 640 Ω, OUT0 to OUT15
Constant sink current error
0.5
No data transfer, all output OFF, VO = 1 V, R(IREF) = 10 kΩ
IO(LC)
ΔIO(LC0)
UNIT
V
VI = VCC; MODE pin
ICC
MAX
VCC – 0.5
(1)
±1
±8
All output ON, VO = 1 V, R(IREF) = 320 Ω, VCC > 3.6 V, OUT0 to
OUT15,
–20°C to +85°C (1)
±1
±6
All output ON, VO = 1 V, R(IREF) = 320 Ω, VCC > 3.6 V, OUT0 to
OUT15 (1)
±1
±8
%
ΔIO(LC1)
Constant sink current error
Device to device, averaged current from OUT0 to OUT15,
R(IREF) = 1920 Ω (20 mA) (2)
–2, +0.4
±4
%
ΔIO(LC2)
Constant sink current error
Device to device, averaged current from OUT0 to OUT15,
R(IREF) = 480 Ω (80 mA) (2)
–2.7, +2
±4
%
All output ON, VO = 1 V, R(IREF) = 640 Ω OUT0 to OUT15,
VCC = 3 V to 5.5 V (3)
±1
±4
%/V
All output ON, VO = 1 V, R(IREF) = 320 Ω OUT0 to OUT15,
VCC > 3.6 V (3)
±1
±6
%/V
ΔIO(LC3)
Line regulation
All output ON, VO = 1 V to 3 V, R(IREF) = 640 Ω, OUT0 to OUT15 (4)
±2
±6
%/V
ΔIO(LC4)
Load regulation
All output ON, VO = 1 V to 3 V, R(IREF) = 320 Ω, VCC > 3.6 V, OUT0 to
OUT15 (4)
±2
±8
%/V
T(TEF)
Thermal error flag threshold
Junction temperature (5)
V(LED)
LED open detection
threshold
V(IREF)
Reference voltage output
(1)
(2)
(3)
(4)
(5)
4
R(IREF) = 640 Ω
+150
1.20
+170
°C
0.3
0.4
V
1.24
1.28
V
The deviation of each output from the average of OUT0-15 constant current. It is calculated by Equation 1 in Table 1.
The deviation of average of OUT1-15 constant current from the ideal constant-current value. It is calculated by Equation 2 in Table 1.
The ideal current is calculated by Equation 3 in Table 1.
The line regulation is calculated by Equation 4 in Table 1.
The load regulation is calculated by Equation 5 in Table 1.
Not tested. Specified by design.
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SBVS137 – DECEMBER 2009
Table 1. Test Parameter Equations
D(%) =
D(%) =
I OUTn - I OUTavg _ 0 -15
IOUTavg _ 0 -15
IOUTavg - I OUT (IDEAL )
I OUT (IDEAL )
´ 100
(1)
´ 100
(2)
æ 1.24 V ö
÷÷
IOUT (IDEAL ) = 31.5 ´ çç
è R IREF ø
D(% / V ) =
D(% / V ) =
(3)
(IOUTn at VCC = 5.5 V ) - (I OUTn at VCC = 3.0 V ) 100
´
(I OUTn at VCC = 3.0 V )
2.5
(4)
(IOUTn at VOUTn = 3.0 V ) - (IOUTn at VOUTn = 1.0 V ) 100
´
(IOUTn at VOUTn = 1.0 V )
2 .0
(5)
SWITCHING CHARACTERISTICS
At VCC = 3 V to 5.5 V, CL = 15 pF, and TA = –40°C to 85°C, unless otherwise noted.
PARAMETER
tr0
tr1
tf0
tf1
Rise time
Fall time
TEST CONDITIONS
MIN
TYP
SOUT
MAX
16
OUTn, VCC = 5 V, TA = +60°C, DCn = 3Fh
10
SOUT
30
16
OUTn, VCC = 5 V, TA = +60°C, DCn = 3Fh
10
30
UNIT
ns
ns
tpd0
SCLK - SOUT (see Figure 12)
30
ns
tpd1
BLANK - OUT0 (see Figure 12)
60
ns
tpd2
1000
ns
tpd3
GSCLK - OUT0 (see Figure 12)
60
ns
tpd4
XLAT - IOUT (dot correction) (see Figure 12)
60
ns
20
30
ns
–50
10
ns
td
ton_err
Propagation delay time
OUTn - XERR (see Figure 12)
Output delay time
OUTn - OUT(n+1) (see Figure 12)
Output on-time error
touton – Tgsclk (see Figure 12), GSn = 01h,
GSCLK = 11 MHz
–90
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PIN CONFIGURATIONS
PWP PACKAGE
28-PIN HTSSOP PowerPAD
(TOP VIEW)
XLAT
3
26
TEST
SCLK
4
25
GSCLK
SIN
5
24
MODE
6
OUT0
7
OUT1
8
OUT2
TEST
IREF
IREF
27
VCC
2
NC
BLANK
(1)
VCC
NC
28
GND
1
BLANK
GND
XLAT
RHB PACKAGE
32-PIN 5 mm × 5 mm QFN
(TOP VIEW)
32
31
30
29
28
27
26
25
SCLK
1
24
GSCLK
SOUT
SIN
2
23
SOUT
23
XERR
MODE
3
22
XERR
22
OUT15
OUT0
4
21
OUT15
21
OUT14
OUT1
5
20
OUT14
9
20
OUT13
OUT2
6
19
OUT13
OUT3
10
19
OUT12
OUT3
7
18
OUT12
OUT4
11
18
OUT11
OUT4
8
17
OUT11
OUT5
12
17
OUT10
OUT6
13
16
OUT9
OUT7
14
15
OUT8
9
10
11
12
13
14
15
16
OUT6
OUT7
NC
NC
OUT8
OUT9
OUT10
Thermal
Pad
OUT5
Thermal
Pad
(1) NC = no connection.
6
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SBVS137 – DECEMBER 2009
TERMINAL FUNCTION
TERMINAL
PWP
RHB
NAME
NO.
NO.
I/O
DESCRIPTION
BLANK
2
31
I
Blank all outputs. When BLANK is high, all OUTn outputs are forced OFF.
GS counter is also reset. When BLANK is low, OUTn are controlled by the
grayscale PWM control.
GND
1
30
G
Ground
GSCLK
25
24
I
Reference clock for grayscale PWM control
IREF
27
26
I/O
NC
-
12, 13, 28, 29
OUT0
7
4
O
Constant-current output. Multiple outputs can be configured in parallel to
increase the constant-current capability. Different voltages can be applied to
each output.
OUT1
8
5
O
Constant-current output
OUT2
9
6
O
Constant-current output
OUT3
10
7
O
Constant-current output
OUT4
11
8
O
Constant-current output
OUT5
12
9
O
Constant-current output
OUT6
13
10
O
Constant-current output
OUT7
14
11
O
Constant-current output
OUT8
15
14
O
Constant-current output
OUT9
16
15
O
Constant-current output
OUT10
17
16
O
Constant-current output
OUT11
18
17
O
Constant-current output
OUT12
19
18
O
Constant-current output
OUT13
20
19
O
Constant-current output
OUT14
21
20
O
Constant-current output
OUT15
22
21
O
Constant-current output
SCLK
4
1
I
Serial data shift clock
Reference current terminal. The maximum current for the outputs
OUT0-OUT15 is set with a resistor from IREF to GND. Any capacitance does
not need to be connected between IREF and GND.
No connection
SIN
5
2
I
Serial data input
SOUT
24
23
O
Serial data output
TEST
26
25
I
Test pin: TEST must be connected to VCC
VCC
28
27
I
Power-supply voltage
MODE
6
3
I
Input mode-change pin. When MODE = GND, the device is in GS mode.
When MODE = VCC, the device is in DC mode.
XERR
23
22
O
Error output. XERR is an open-drain terminal. XERR goes low when LOD or
TEF is detected.
XLAT
3
32
I
Level triggered latch signal. When XLAT is high, the TLC59401 writes data
from the input shift register to either GS register (MODE is low) or DC
register (MODE is high). When XLAT is low, the data in the GS or DC
registers are held constant and do not change.
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PARAMETER MEASUREMENT INFORMATION
PIN EQUIVALENT INPUT AND OUTPUT SCHEMATIC DIAGRAMS
Resistor values are equivalent resistance and not tested.
INPUT EQUIVALENT CIRCUIT
(BLANK, XLAT, SCLK, SIN, GSCLK, TEST)
OUTPUT EQUIVALENT CIRCUIT (SOUT)
VCC
23 400 INPUT
SOUT
23 GND
GND
INPUT EQUIVALENT CIRCUIT (IREF)
OUTPUT EQUIVALENT CIRCUIT (XERR)
VCC
_
400 INPUT
23 Amp
XERR
+
100 GND
GND
INPUT EQUIVALENT CIRCUIT (VCC)
OUTPUT EQUIVALENT CIRCUIT (OUT)
OUT
INPUT
GND
GND
INPUT EQUIVALENT CIRCUIT (MODE)
INPUT
GND
Figure 2. Input and Output Equivalent Circuits
8
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PARAMETER MEASUREMENT INFORMATION (continued)
t wh0 , t wIO, twh1, twl1, tsu0
t su4, th4
V(LED) = 4 V
SOUT
Test Point
RL = 51
CL = 15 pF
OUTn
Test Point
CL = 15 pF
IOLC, IOLC3, IOLC4
V(LED) = 1 V
OUT0
VCC = 0 V ~ 7 V
OUTn
+ _
OUT15
IREF
Test Point
RIREF = 640
Figure 3. Parameter Measurement Circuits
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TYPICAL CHARACTERISTICS
REFERENCE RESISTOR
vs
OUTPUT CURRENT
POWER DISSIPATION RATE
vs
FREE-AIR TEMPERATURE
4k
10 k
TLC59401PWP
PowerPAD Soldered
7.68 kW
1.92 kW
1k
0.96 kW
0.64 kW
0.48 kW
0.38 kW
Power Dissipation Rate - mW
Reference Resistor, R(IREF) - W
TLC59401RHB
0.32 kW
100
0
20
40
60
80
100
3k
2k
TLC59401PWP
PowerPAD Unsoldered
1k
0
120
-40
IO - Output Current - mA
-20
0
40
20
Figure 4.
Figure 5.
OUTPUT CURRENT
vs
OUTPUT VOLTAGE
OUTPUT CURRENT
vs
OUTPUT VOLTAGE
140
65
TA = +25°C,
VCC = 5 V
IO = 120 mA
80
100
IO = 60 mA,
VCC = 5 V
64
120
TA = +85°C
63
IO = 100 mA
100
IO - Output Current - mA
IO - Output Current - mA
60
TA - Free-Air Temperature - °C
IO = 80 mA
80
IO = 60 mA
60
IO = 40 mA
40
62
61
TA = +25°C
60
TA = -40°C
59
58
IO = 20 mA
57
IO = 5 mA
56
20
0
55
0
0.5
1.0
1.5
2.0
2.5
3.0
0
VO - Output Voltage - V
1.0
1.5
2.0
2.5
3.0
VO - Output Voltage - V
Figure 6.
10
0.5
Figure 7.
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TYPICAL CHARACTERISTICS (continued)
CONSTANT OUTPUT CURRENT, ΔIOLC
vs
AMBIENT TEMPERATURE
CONSTANT OUTPUT CURRENT, ΔIOLC
vs
OUTPUT CURRENT
8
8
TA = +25°C,
VCC = 5 V
IO = 60 mA
6
D IOLC - Constant Output Current - %
D IOLC - Constant Output Current - %
6
4
VCC = 3.3 V
2
0
-2
VCC = 5 V
-4
4
2
0
-2
-4
-6
-6
-8
-40
-8
0
-20
20
40
60
80
0
100
20
60
80
Figure 8.
Figure 9.
OUTPUT CURRENT
vs
DOT CORRECTION LINEARITY (ABS Value)
OUTPUT CURRENT
vs
DOT CORRECTION LINEARITY (ABS Value)
140
70
TA = +25°C,
VCC = 5 V
IO = 60 mA,
VCC = 5 V
IO = 120 mA
120
TA = +25°C
60
100
IO - Output Current - mA
IO - Output Current - mA
40
IO - Output Current - mA
TA - Ambient Temperature - °C
IO = 80 mA
80
IO = 60 mA
60
40
IO = 30 mA
20
50
TA = +85°C
TA = -40°C
40
30
20
10
IO = 5 mA
0
0
0
10
20
30
40
50
60
70
0
10
20
30
40
50
60
70
Dot Correction Data - dec
Dot Correction Data - dec
Figure 10.
Figure 11.
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PRINCIPLES OF OPERATION
SERIAL INTERFACE
The TLC59401 has a flexible serial interface, which can be connected to microcontrollers or digital signal
processors in various ways. Only three pins are needed to input data into the device. The rising edge of SCLK
signal shifts the data from the SIN pin to the internal register. After all data are clocked in, a high-level pulse of
XLAT signal latches the serial data to the internal registers. The internal registers are level-triggered latches of
XLAT signal. All data are clocked in MSB first. The length of serial data is 96 bit or 192 bit, depending on the
programming mode. Grayscale data and dot correction data can be entered during a grayscale cycle. Although
new grayscale data can be clocked in during a grayscale cycle, the XLAT signal should only latch the grayscale
data at the end of the grayscale cycle. Latching in new grayscale data immediately overwrites the existing
grayscale data. Figure 12 shows the serial data input timing chart. More than two TLC59401s can be connected
in series by connecting an SOUT pin from one device to the SIN pin of the next device. An example of cascading
two TLC59401s is shown in Figure 13 and the timing chart is shown in Figure 14. The SOUT pin can also be
connected to the controller to receive status information from TLC59401, as shown in Figure 22.
MODE
DC Data Input Mode
GS Data Input Mode
th3
tsu3
twh2
XLAT
1st GS Data Input Cycle
SIN
DC
MSB
DC
LSB
SCLK
GS1
LSB
tsu2
th2
GS2
MSB
GS2
LSB
th1
tsu1
1
96
1
2nd GS Data Input Cycle
GS1
MSB
192
GS3
MSB
tsu0
twh0
193
th0
193
192
1
tpd0
twl0
-
SOUT
DC
MSB
-
GS1
MSB
-
1
SID1 SID1
MSB MSB-1
SID2 SID2
MSB MSB-1
SID1 GS2
LSB MSB
twh3
BLANK
First GS Data Output Cycle
tsu5
GSCLK
Second GS Data Output Cycle
1
tpd4
1
4096
tpd3
tpd1
tpd3 + td
td
tpd1 + td
twl1
Tgsclk
tpd3
OUT0
(current)
twh1
tsu4
th4
touton
OUT1
(current)
15 x td
tpd1 + 15 x td
OUT15
(current)
tpd2
XERR
Figure 12. Serial Data Input Timing Chart
SIN(a)
SIN
SOUT
TLC59401 (a)
SIN
SOUT
SOUT(b )
TLC59401 (b)
SCLK, XLAT,
BLANK,
GSCLK,
MODE
,
,
Figure 13. Cascading Two TLC59401 Devices
12
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MODE
XLAT
SIN(a)
SCLK
DCb
MSB
DCa
LSB
GSb1
MSB
192
1
1
GSa1
LSB
384
-
385
GSa2
LSB
GSb3
MSB
385
384
1
1
192X2
96X2
SOUT(b)
GSb2
MSB
DCb
MSB
-
GSb1
MSB
-
SIDb1 SIDb1
MSB MSB-1
SIDa1
LSB
SIDb2 SIDb2
MSB MSB-1
GSb2
MSB
BLANK
1
GSCLK
1
4096
OUT0
(current)
OUT1
(current)
OUT15
(current)
XERR
Figure 14. Timing Chart for Two Cascaded TLC59401 Devices
ERROR INFORMATION OUTPUT
The open-drain output XERR is used to report both of the TLC59401 error flags, TEF and LOD. During normal
operation, the internal transistor connected to the XERR pin is turned off. The voltage on XERR is pulled up to
VCC through an external pull-up resistor. If TEF or LOD is detected, the internal transistor is turned on, and XERR
is pulled to GND. Because XERR is an open-drain output, multiple ICs can be ORed together and pulled up to
VCC with a single pull-up resistor. This capability reduces the number of signals needed to report a system error
(see Figure 22).
To differentiate the LOD and TEF signal from the XERR pin, LOD can be masked out with BLANK pulled high.
Table 2. XERR Truth Table
ERROR CONDITION
ERROR INFORMATION
TEMPERATURE
OUTn VOLTAGE
TEF
LOD
TJ < T(TEF)
Don't care
Low
X
TJ > T(TEF)
Don't care
High
X
OUTn > V(LED)
Low
Low
OUTn < V(LED)
Low
High
OUTn > V(LED)
High
Low
OUTn < V(LED)
High
High
TJ < T(TEF)
TJ > T(TEF)
SIGNALS
BLANK
High
XERR
High
Low
High
Low
Low
Low
Low
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TEF: THERMAL ERROR FLAG
The TLC59401 provides a temperature error flag (TEF) circuit to indicate an over-temperature condition of the IC.
If the junction temperature exceeds the threshold temperature (+160°C typical), TEF goes high and the XERR
pin goes to a low level. When the junction temperature becomes lower than the threshold temperature, TEF goes
low and the XERR pin becomes high impedance. The TEF status can also be read out from the TLC59401
status register.
LOD: LED OPEN DETECTION
The TLC59401 has an LED-open detection circuit that detects broken or disconnected LEDs. The LED open
detector pulls the XERR pin to GND when an open LED is detected. XERR and the corresponding error bit in the
Status Information Data is only active under the following open LED conditions:
1. OUTn is on and the time tpd2 (1 μs typical) has passed.
2. The voltage of OUTn is < 0.3V (typical)
The LOD status of each output can be also read out from the SOUT pin. See the Status Information Output
section for details. The LOD error bits are latched into the Status Information Data when XLAT returns to a low
state after a high state. Therefore, the XLAT pin must be pulsed high, then low while XERR is active in order to
latch the LOD error into the Status Information Data for subsequent reading via the serial shift register.
DELAY BETWEEN OUTPUTS
The TLC59401 has graduated delay circuits between outputs. These circuits can be found in the constant-current
driver block of the device (see Figure 1). The fixed-delay time is 20 ns (typical), OUT0 has no delay, OUT1 has
20 ns delay, and OUT2 has 40 ns delay, etc. The maximum delay is 300 ns from OUT0 to OUT15. The delay
works during switch on and switch off of each output channel. These delays prevent large inrush currents which
reduces the bypass capacitors when the outputs turn on.
OUTPUT ENABLE
All OUTn channels of the TLC59401 can be switched off with one signal. When BLANK is set high, all OUTn
channels are disabled, regardless of logic operations of the device. The grayscale counter is also reset. When
BLANK is set low, all OUTn channels work under normal conditions. If BLANK goes low and then back high
again in less than 300 ns, all outputs programmed to turn on do so for either the programmed number of
grayscale clocks or the length of time that the BLANK signal was low, whichever is lower. For example, if all
outputs are programmed to turn on for 1 ms, but the BLANK signal is only low for 200 ns, all outputs turn on for
200 ns even though some outputs are turning on after the BLANK signal has already gone high.
Table 3. BLANK Signal Truth Table
14
BLANK
OUT0 - OUT15
Low
Normal condition
High
Disabled
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SETTING MAXIMUM CHANNEL CURRENT
The maximum output current per channel is programmed by a single resistor, R(IREF), which is placed between
IREF pin and GND pin. The voltage on IREF is set by an internal band gap V(IREF) with a typical value of
1.24 V. The maximum channel current is equivalent to the current flowing through R(IREF) multiplied by a factor of
31.5. The maximum output current can be calculated by Equation 6:
V
(IREF)
I max +
31.5
R
(IREF)
(6)
where:
V(IREF) = 1.24 V
R(IREF) = User-selected external resistor.
Imax must be set between 5 mA and 120 mA. The output current may be unstable if Imax is set lower
than 5 mA. Output currents lower than 5 mA can be achieved by setting Imax to 5 mA or higher and then
using dot correction.
See Figure 4 for the maximum output current IO versus R(IREF). R(IREF) is the value of the resistor between IREF
terminal to GND, and IO is the constant output current of OUT0 to OUT15. A variable power supply may be
connected to the IREF pin through a resistor to change the maximum output current per channel. The maximum
output current per channel is 31.5 times the current flowing out of the IREF pin.
POWER DISSIPATION CALCULATION
The device power dissipation must be below the power dissipation rate of the device package to ensure correct
operation. Equation 7 calculates the power dissipation of device:
P
D
ǒ
+ V
CC
I
Ǔ ) ǒVOUT
CC
I
MAX
N
DCn
63
d
PWM
Ǔ
(7)
where:
VCC: device supply voltage
ICC: device supply current
VOUT: TLC59401 OUTn voltage when driving LED current
IMAX: LED current adjusted by R(IREF) Resistor
DCn: maximum dot correction value for OUTn
N: number of OUTn driving LED at the same time
dPWM: duty cycle defined by BLANK pin or GS PWM value
OPERATING MODES
The TLC59401 has two operating modes defined by MODE as shown in Table 4. The GS and DC registers are
set to random values that are not known immediately after power on. The GS and DC values must be
programmed before turning on the outputs. Please note that when initially setting GS and DC data after power
on, the GS data must be set before the DC data is set. Failure to set GS data before DC data may result in
losing the first bit of GS data. XLAT must be low when the MODE pin goes high-to-low or low-to-high to change
back and forth between GS mode and DC mode.
Table 4. TLC59401 Operating Modes Truth Table
MODE
INPUT SHIFT REGISTER
OPERATING MODE
GND
192 bit
Grayscale PWM Mode
VCC
96 bit
Dot Correction Data Input Mode
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SETTING DOT CORRECTION
The TLC59401 has the capability to fine-adjust the output current of each channel (OUT0 to OUT15)
independently. This feature is also called dot correction. This feature is used to adjust the brightness deviations
of LEDs connected to the output channels OUT0 to OUT15. Each of the 16 channels can be programmed with a
6-bit word. The channel output can be adjusted in 64 steps from 0% to 100% of the maximum output current Imax.
The TEST pin must be connected to VCC to ensure proper operation of the dot correction circuitry. Equation 8
determines the output current for each output n:
I
+ I max DCn
OUTn
63
(8)
where:
Imax = the maximum programmable output current for each output.
DCn = the programmed dot correction value for output n (DCn = 0 to 63).
n = 0 to 15
Figure 15 shows the dot correction data packet format which consists of 6 bits x 16 channel, total 96 bits. The
format is Big-Endian format. In this format, the MSB is transmitted first, followed by the MSB-1, etc. The DC 15.5
in Figure 15 stands for the fifth-most significant bit for output 15.
MSB
LSB
0
5
6
89
90
95
DC 15.5
DC 15.0
DC 14.5
DC 1.0
DC 0.5
DC 0.0
DC OUT15
DC OUT0
DC OUT14 − DC OUT1
Figure 15. Dot Correction Data Packet Format
When MODE is set to VCC, the TLC59401 enters the dot correction data input mode. The length of the input shift
register becomes 96 bits. After all serial data are shifted in, the TLC59401 writes the data in the input shift
register to the DC register when XLAT is high, and holds the data in the DC register when XLAT is low. The DC
register is a level-triggered latch of the XLAT signal. Because XLAT is a level-triggered signal, SCLK and SIN
must not be changed while XLAT is high. After XLAT goes low, data in the DC register are latched and do not
change. The BLANK signal does not need to be high to latch in new data. When XLAT goes high, the new
dot-correction data immediately become valid and change the output currents if BLANK is low. XLAT has a setup
time (tsu1) and a hold time (th1) to SCLK, as shown in Figure 12.
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To input data into the dot correction register, MODE must be set to VCC. The internal input shift register is then
set to 96-bit width. After all serial data are clocked in, a rising edge of XLAT is used to latch the data into the dot
correction register. Figure 16 shows the dc data input timing chart.
DC Mode Data
Input Cycle n
DC Mode Data
Input Cycle n+1
VCC
MODE
SIN
DC n−1
LSB
DC n
MSB
DC n
MSB−1
DC n
MSB−2
DC n
LSB+1
DC n
LSB
DC n+1
MSB
DC n+1
MSB−1
twh0
SCLK
1
2
3
95
96
1
2
twl0
SOUT
DC n−1
MSB
DC n−1
MSB−1
DC n−1
MSB−2
DC n−1
LSB+1
DC n−1
LSB
tsu1
DC n
MSB
DC n
MSB−1
DC n
MSB−2
twh2
th1
XLAT
Figure 16. Dot Correction Data Input Timing Chart
When the IC is powered on, the data in the input shift register and DC register are not set to any default values.
Therefore, DC data must be written to the DC register before turning on the constant-current output.
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SETTING GRAYSCALE
The TLC59401 can adjust the brightness of each channel OUTn using a PWM control scheme. The use of 12
bits per channel results in 4096 different brightness steps, from 0% to 100% brightness. Equation 9 determines
the brightness level for each output n:
Brightness in % + GSn
100
4095
(9)
where:
GSn = the programmed grayscale value for output n (GSn = 0 to 4095)
n = 0 to 15
Grayscale data for all OUTn
The input shift register enters grayscale data into the grayscale register for all channels simultaneously. The
complete grayscale data format consists of 16 × 12 bit words, which forms a 192-bit wide data packet (see
Figure 17). The data packet must be clocked in MSB first.
MSB
0
11
12
179
180
LSB
191
GS 15.11
GS 15.0
GS 14.11
GS 1.0
GS 0.11
GS 0.0
GS OUT15
GS OUT14 − GS OUT1
GS OUT0
Figure 17. Grayscale Data Packet Format
When MODE is set to GND, the TLC59401 enters grayscale data input mode. The device switches the input shift
register to 192-bit width. After all data are clocked in, a rising edge of the XLAT signal latches the data into the
grayscale register (see Figure 18). New grayscale data immediately become valid at the rising edge of the XLAT
signal; therefore, new grayscale data should be latched at the end of a grayscale cycle when BLANK is high. The
first GS data input cycle after dot correction requires an additional SCLK pulse after the XLAT signal to complete
the grayscale update cycle. All GS data in the input shift register are replaced with status information data (SID)
after updating the grayscale register.
DC Mode Data
Input Cycle
Following GS Mode Data
Input Cycle
First GS Mode Data
Input Cycle After DC Data Input Cycle
MODE
t h3
t h3
t su3
XLAT
t wh2
SIN
GS
MSB
DC
LSB
GS n + 1
LSB
t h1
t h2
SCLK
GS + 1
MSB
GS
LSB
t su1
t su2
1
96
192
193
1
192
t pd0
n
SOUT DC
LSB
DC
MSB
X
X
GS
MSB
SID
MSB
SID
MSB−1
SID
LSB
SID n + 1
MSB
Figure 18. Grayscale Data Input Timing Chart
When the IC is powered on, the data in the input shift register and GS register are not set to any default values.
Therefore, GS data must be written to the GS register before turning on the constant-current output.
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STATUS INFORMATION OUTPUT
The TLC59401 has a status information register, which can be accessed in grayscale mode (MODE = GND).
After the XLAT signal latches the data into the GS register, the input shift register data are replaced with the
status information data (SID) of the device (see Figure 18). LOD, TEF, and dot-correction register data can be
read out at the SOUT pin. The status information data packet is 192 bits wide. Bits 0 to 15 contain the LOD
status of each channel. Bit 16 contains the TEF status. Bits 24 to 119 contain the data of the dot-correction
register. The remaining bits are reserved. The complete status information data packet is shown in Figure 19.
SOUT outputs the MSB of the SID at the same time the SID are stored in the SID register, as shown in
Figure 20. The next SCLK pulse, which is the clock for receiving the MSB of the next grayscale data, transmits
MSB-1 of the SID. If the output voltage is less than 0.3 V (typical) when the output sink current turns on, the LOD
status flag becomes active. The LOD status flag is an internal signal that pulls the XERR pin low when the LOD
status flag becomes active. The delay time, tpd2 (1 μs maximum), is the period from the time of turning on the
output sink current to the time the LOD status flag becomes valid. The timing for each channel LOD status to
become valid is shifted by the 30-ns (maximum), channel-to-channel turn-on time. After the first GSCLK goes
high, OUT0 LOD status is valid; tpd3 + tpd2 = 60 ns + 1 μs = 1.06 μs. OUT1 LOD status is valid; tpd3 + td + tpd2 =
60 ns + 30 ns + 1 μs = 1.09 μs. OUT2 LOD status is valid; tpd3 + (2 × td) + tpd2 = 1.12 μs, and so on. It takes 1.51
μs maximum (tpd3 + (15 × td) + tpd2) from the first GSCLK rising edge until all LOD become valid; tsuLOD must be
greater than 1.51 μs (see Figure 20) to ensure that all LOD data are valid.
MSB
LSB
0
15
16
LOD 15
LOD 0
TEF
LOD Data
23
X
X
TEF
24
DC 15.5
119
120
191
DC 0.0
X
X
DC Values
Reserved
Figure 19. Status Information Data Packet Format
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MODE
GS Data Input Mode
tsuLOD > tpd3 + td ´ 15 + tpd2
tsuLOD
XLAT
First GS Data Input Cycle
Second GS Data Input Cycle
SIN
GS1
MSB
GS1
LSB
SCLK
1
192
SOUT
-
-
GS2
MSB
193
GS1
MSB
GS2
LSB
192
1
SID1
MSB
SID1
MSB-1
SID1
LSB
GS2
MSB
(1st GS Data Output Cycle)
BLANK
GSCLK
4096
1
tpd3
OUT0
(current)
td
OUT1
(current)
15 x td
OUT15
(current)
tpd2
XERR
tpd3 + 15 x td + tpd2
Figure 20. Readout Status Information Data (SID) Timing Chart
The LOD status of each output can be read out from the SOUT pin. The LOD error bits are latched into the
Status Information Data when XLAT returns to a low after a high. Therefore, the XLAT pin must be pulsed high
then low while XERR is active in order to latch the LOD error into the Status Information Data for subsequent
reading via the serial shift register.
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GRAYSCALE PWM OPERATION
The grayscale PWM cycle starts with the falling edge of BLANK. The first GSCLK pulse after BLANK goes low
increases the grayscale counter by one and switches on all OUTn with a grayscale value not equal to zero. Each
following rising edge of GSCLK increases the grayscale counter by one. The TLC59401 compares the grayscale
value of each output OUTn with the grayscale counter value. All OUTn with grayscale values equal to the
counter values are switched off. A high BLANK signal after 4096 GSCLK pulses resets the grayscale counter to
zero and completes the grayscale PWM cycle ,as Figure 21 shows. When the counter reaches a count of FFFh,
the counter stops counting and all outputs turn off. Pulling BLANK high before the counter reaches FFFh
immediately resets the counter to zero.
If there are any unconnected outputs (OUTn), including LEDs in a failed short or failed open condition, the GS
data corresponding to the unconnected output should be set to '0' before turning on the LEDs. Otherwise, the
VCC supply current (ICC) increases while the constant-current output is on.
GS PWM
Cycle n
BLANK
t wl1
t wh1
t h4
GSCLK
1
OUT0
(Current)
OUT1
(Current)
t pd1
t pd1 + td
GS PWM
Cycle n+1
2
t pd3
4096
3
t wl1
t wh3
t su4
1
t pd3
nxt d
t pd3+ n x t d
t pd1 + 15 x td
OUT15
(Current)
t pd2
XERR
Figure 21. Grayscale PWM Cycle Timing Chart
Output On-Time
The amount of time that each output is turned on is a function of the grayscale clock frequency and the
programmed grayscale PWM value. The on-time of each output can be calculated using Equation 10.
GSn
T _ on n =
+ t on _ err
f( GSCLK )
(10)
where:
T_onn is the time that OUTn turns on and sinks current
GSn is the OUTn programmed grayscale PWM value between 0 and 4095
ton_err is the output on-time error defined in the Switching Characteristics Table
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When using Equation 10 with very high GSCLK frequencies and very low grayscale PWM values, the resulting
T_on-time may be negative. If T_on is negative, the output does not turn on. For example, using f(GSCLK) = 30
MHz, GSn = 1, and the typical ton_err = 50 ns, Equation 10 calculates that OUTn turns on for –16.6 ns. This
output may not turn on under these conditions. Increasing the PWM value or reducing the GSCLK clock
frequency ensures turn-on.
SERIAL DATA TRANSFER RATE
Figure 22 shows a cascading connection of n TLC59401 devices connected to a controller, building a basic
module of an LED display system. There is no TLC59401 limitation to the maximum number of ICs that can be
cascaded. The maximum number of cascading TLC59401 devices depends on the application system.
Equation 11 calculates the minimum frequency needed:
f
+ 4096
f
(GSCLK)
(update)
f
(SCLK)
+ 193
f
(update)
n
(11)
where:
f(GSCLK): minimum frequency needed for GSCLK
f(SCLK): minimum frequency needed for SCLK and SIN
f(update): update rate of whole cascading system
n: number cascaded of TLC59401 device
APPLICATION EXAMPLE
VCC
V(LED)
V(LED)
V(LED)
V(LED)
100 k
OUT0
SIN
XERR
XERR
SCLK
SCLK
XLAT
GSCLK
MODE
BLANK
SOUT
OUT15
SIN
SOUT
XERR
VCC
VCC
SCLK
100 nF
GSCLK
IREF
BLANK
IC 0
TLC59401
IREF
MODE
VCC
TEST
100 nF
XLAT
TLC59401
MODE
VCC
OUT0
SOUT
XLAT
GSCLK
Controller
OUT15
SIN
BLANK
TEST
IC n
6
Figure 22. Cascading Devices
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PACKAGE OPTION ADDENDUM
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23-Dec-2009
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
TLC59401PWP
ACTIVE
HTSSOP
PWP
28
TLC59401PWPR
ACTIVE
HTSSOP
PWP
TLC59401RHBR
ACTIVE
QFN
TLC59401RHBT
ACTIVE
QFN
50
Lead/Ball Finish
MSL Peak Temp (3)
Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
28
2000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
RHB
32
3000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
RHB
32
250
CU NIPDAU
Level-2-260C-1 YEAR
Green (RoHS &
no Sb/Br)
(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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