Datasheet

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Timingclock for 1st display and

2nddisplay datawrite.

ShiftClock

for 2nd Display

for

2nd

LSB

for

255th

ShiftData From

Controller (SDTI)

ShiftClock From

Controller(SCKI)

OUTXn

VLED Power

224 Shift Clocks

224-BitPacket for

256th TLC59711

8192

Shift Clocks

MSB

224-BitPacket

for 1st TLC59711

OUTXnis controlled viathe PWM synchronized

with SCKIfor 1st displayperiod.

Thetimeis8periodsbetweenthelast SCLKrisingedgeandthe secondtolast SCLKrising edge.

Thewaittimechangesbetween 2.74ms and666 ns, dependingontheperiod of theshift clock.

Thenext shiftclockshould startafter 1.34 sormore fromthe internallatch pulse generationtiming.m

256 224-BitPacketfor

256th TLC59711

Low

57344(256 224)

ShiftClocks

Latch Pulse

(Internal)

Low

OFF

2nd Display

Period

Timingclock for1st display.

MSB LSB MSB LSB

224 Shift Clocks

224 256 = 57344Clocks´ 65536Clocks 65536Clocks

TLC59711

www.ti.com

SBVS181A –OCTOBER 2011–REVISED JULY 2012

There is another control procedure that is recommended for a long chain of cascaded devices. The data and

clock timings are shown in Figure 9 and Figure 35. When 256 TLC59711 units are cascaded, use the following

procedure:

1. Power up VCC (VLED); all OUTXn are off because BLANK is set to '1'.

2. Write the 224-bit data packet MSB-first for the 256th TLC59711 using the SDTI and SCKI signals. The

EXTCLK bit must be set to '1' for the external oscillator mode. Also, the DSPRPT bit should be set to '0' so

that the PWM control does not repeat, the TMGRST bit should be set to '1' to reset the PWM control timing

with the internal latch pulse, and BLANK must be set to '0' to start the PWM control.

3. Repeat the data write sequence for all TLC59711s. The total shift clock count (SCKI) is 57344 (224 × 256).

After all device data are written, stop the SCKI signal at a high or low level for eight or more periods between

the last SCKI rising edge and the second to last SCKI rising edge. Then the 218 LSBs in the 224-bit shift

resister are copied to the 218-bit data latch in all devices.

4. To control the PWM, send 8192 SCKI clock periods with SDTI low after 1.34µs or more from step 3 (or step

7). These 8192 clock periods are used for the OUTXn PWM control.

5. Write the new 224-bit data packets to the 256th to first TLC59711s for the next display with 256 × 224 SCKI

clock for a total of 57344 clocks. The PWM control for OUTXn remains synchronized with the SCKI clock and

one display period is finished with a total of 65536 SCKI clocks. The SCKI clock signal is therefore used for

PWM control and, at the same time, to write data into the shift registers of all cascaded parts.

6. Stop the SCKI signal at a high or low level for eight or more periods between the last SCKI rising edge and

the second to last SCKI rising edge. Then the 218-bit LSBs in the 224-bit shift resister are copied to the 218-

bit data latch in all devices.

7. Repeat step 4 to step 6 for the next display periods.

Figure 35. Data Packet and Display Start/Update Timing 3

(External Clock Mode with 256 Cascaded Devices)

Product Folder Link(s): TLC59711