We decided to use the TLC5957 LED driver of Texas Instruments with Broadcom RGB LEDs: ASMB-KTF0-0A306.
First, we have to determine the maximum current which will be used. The 3 colours of the RGB LEDs can get a 20 mA input current max and the driver can handle 20mA sink current max. So we choose a maximum current of 20mA.
We decided to configure the driver with the maximum value for the Brightness Control (BC) (and by consequence, the maximum gain) to provide the intensity to go over 20mA. So we have to choose a value of BC equals to 7. And to limit the current to 20mA max we have to put a 9.27kΩ IREF resistor between IREF and IREFGND pins.
After that, we have to choose the Colour control for each colour. This parameter is used to choose for each colour, the ratio between the maximum output current for this colour and the maximum output of the driver. This is used to tune the white balance. According to the LEDs datasheet, the mean intensities are 490mcd for Red, 1100mcd for Green, 215mcd for Blue. So, to have the same mean intensity for each colour, we have to choose those values for CC: 224 for Red, 100 for Green, 511 for Blue.
The main mode of this driver is done to be used with 16-bits colours. However, we want to use it with 9-bits colours. So, we have to use the other mode: the Poker Mode. When we choose the Poker Mode, we have to activate the ES-PWM and the XREFRESH.
The driver contains several registers. We will use the 4 main ones. The first one is the Common shift register (48bits). Every data one wants to input has to be written in this register. The second one is the FC data latch (48bits). This register is used to configure the driver. Both last ones are GS data latches 1 and 2 (768bits each). They are used to save the data and prepare it to be sent to the LEDs.
The communication between registers is led by the SCK clock and the LAT signal.
First, we have to configure the driver so, we have to configure the FC data latch. To do so, we send bit after bit the 48bits configuration from the MSB to the LSB. In this configuration, we specify different values like the BC, the CC for each colour. We also activate the Poker mode, the ES-PWM and disable the XREFRESH. After sending the 48bits, we send the FCWTREN (LAT high for 15 rising edges) command then the WRTFC (LAT high for 5 rising edges) as below.
In the traditional mode, we input in the common register the 16bits of each colour from Blue to Red and from MSB to LSB. But, in Poker mode, it is different. We input the bit n of the Blue of the 15th LED then, the bit n of the Green of the 15th LED … until the bit n of the Red of the 0th LED.
So because we use 9-bits colours, we have to first send the Bit 8 of the colours of 16 LEDs then the Bit 8 etc until the Bit 0. Then we output everything. So how does this work? When one has input in the common register the 48 bits data which represent the Bit 8 of the colours of 16 LEDs, one sends WRTGS command (LAT high during one rising edge). This command will copy the 48 bits of the common register in the 1st GS Latch at the address of Bit 8 (address given by the GS data bit address counter). Then the GS data bit address counter is decreased 1. The process is the same for Bits 7 to 1. For Bit 0, one uses the LATGS command (LAT high during three rising edges). This command will do the same thing as WRTGS but, it will also copy the entire 1st GS latch into the second one, it resets the GS data bit address counter to 8 and increased 1 the LINE counter (it will be useful later). But it also forces out the new values which will be sent to the LEDs.
Just below, an example with 10-bits colours. For 9-bits colours, it is quite the same but there are only 8 calls of WRTGS and the GS data Bit address counter starts at 8.
This is a different approach to realize a PWM. The high state period will be cut and spread to minimize the time between high and low states and get a better result.
For this project, we decided to multiplex LEDs by 4. Indeed, this driver has enough pins to control 16 LEDs but on each column, we have 64 LEDs. The process to write data is quite the same as without multiplexing. However, they are some things new. First, we will now also use a line counter. This counter is here to know in which step of the multiplexing we are; do we display the first 16 LEDs, the second, the third or the fourth ones. This counter is used by the LED Open Detection which is used to prevent the caterpillar effect but we will explain this after.
So now how do we write our data? For the three first groups of 16 LEDs, it is still the same: 8 WRTGS + 1 LATGS. However, for the fourth group, the LATGS method will be replaced by the LINERESET command (LAT high during seven rising edges). This command will do the same things as LATGS but instead of increasing the LINE counter, it will reset it to 1. That means we sent the data on every LED.
The caterpillar effect is a problem caused by broken LEDs in multiplexed architectures. As a result, the LEDs multiplexed with the broken one can blink whereas they should be off when the driver tries to switch on the broken one. The Line Counter and the LINERESET command help the Caterpillar cancelling function to detect the broken LEDs and to automatically turn off the output channel for the specific line (so only turn off the output for the broken LED and not to every LEDs multiplexed with it).
- Let me hear your vox
- FPGA architecture, episode 2
- Tryna catch me drivin' dirty
- Pro (Component) Choice
- The hardest choices require the strongest will
- Weird flex but okay
- A first look at the FPGA architecture
- Wireless power transmission and Motor choice
- Gobal architecture for LitSpin
- Ah, yes. Stereoscopic vision.
- Choosing a shape
- Power and data transmission
- Design Crisis
- Meet LitSpin
- LitSpin: about our project