Transmitter Design

Posted by admin on March 8, 2013

Our transmitter is using the Vishay TSUS5202 IR LED. For best range, we wish to push through the highest current possible; to determine this we check out the data sheet:

current.PNG

 We're driving the transmitter at 38kHz, which means the period is 26us. We run at 50% duty cycle, so pulse duration is 13us. Reading from the 0.5 tp/T line we find If is 300mA.

Supply voltage is 3.3V. From the spec sheet voltage drop is 1.3V; however I have measured at 1.05V. That's at a zero-current state though.

For 300mA, that means we need a current limit resistor at 6.6ohm. 

 


Design Notes - 38khz emitter

Posted by admin on February 11, 2013

Notes on the MSP430-based IR transmitter driver.

We are using this transmitter:

VISHAY SEMICONDUCTOR - TSUS5202 - IR EMITTER, 950NM, T-1 3/4, THROUGH HOLE

from Newark.

Forward voltage is 1.3-1.7 V, nominal forward current is 100ma.

We can't really drive these in pairs from the 3.3V supply; I have been pondering a design where the microcontroller is driven by a CR2032 coin cell and the oomph for the LEDs comes from an auxiliary battery pack that can both be monitored by the microcontroller (with status displayed) and that can have a higher drive voltage as well. 

I have in hand a 5V LDO regulator (MCP1827-5002E/AT). We can drive this from four 1.5V AA cells and have the minimum 5.6V supply for the LDO, and drive sets of pairs of LEDs. We get a bonus where we can monitor the PWRGD line from the regulator, as well as make use of the SHDN input to do microcontroller control of the LED drive. At some point I would like to include a radio transceiver on the LED driver module as well as the detector, for overall system control and monitoring.

Anyway, if we're driving LEDs with Vf = 1.3V from a 5V supply, we can drive strings of three (3.9V, leaving a 1.1V margin away from supply. However if the Vf were closer to 1.7 we might be in trouble. TEST1: measure the Vf on our LEDs).

To drive If=100mA through them, we have Rled = (5V - 3 * 1.3V) / 0.1 = 11 ohms. Closest standard resistor is 10 ohms, making our current 110mA, a bit higher than our target. If the LEDs' Vf is 1.5V, the current would be 50mA.

Current 0.1        
Vcc # leds Vf R R - chosen I
5 2 1.3 24 22 109.1
5 3 1.3 11 10 110
5 2 1.5 20 22 90.9
5 3 1.5 5 25 20
5 2 1.7 16 16 100
5 3 1.7 XXX    

It's a blog, everyone needs a blog

Posted by admin on February 9, 2013

Welcome to the LiveTrial.net blog.

This is mostly a place for Bob to ponder aloud his plans for the LiveTrial ecosystem. 

What is LiveTrial? It's intended to be an open-source hardware and software platform to enable the most efficient running of dog performance events possible.