Difference between revisions of "OPTOUSB"
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** 15 K Ohms for 3.3V operation | ** 15 K Ohms for 3.3V operation | ||
** Top speed is more than 57.6 kbaud with 4N25M optoisolator | ** Top speed is more than 57.6 kbaud with 4N25M optoisolator | ||
+ | * Note: Testing in loopback mode doubles this problem | ||
=== Optoisolator Improvements === | === Optoisolator Improvements === |
Latest revision as of 13:44, 31 October 2022
Contents
- 1 Features
- 2 Block Diagram
- 3 Separate Power Domains
- 4 Connectors
- 5 Drivers
- 6 Layout
- 7 Transfer Rate Characterization
- 8 Opto-Isolator Drive Circuits
- 9 Factory Acceptance Test
- 10 Revision History
- 11 Assembly Sheet
Features
- USB to TTL level Serial (FTDI) Interface
- Genuine FTDI FT230XS part
- Standard FTDI drivers
- Buffered lines on the TTL level side
- Schmidt Trigger
- Voltage level hysteresis
- Improved slew rate
- Schmidt Trigger
- OptoIsolated Connections
- Transmit, Receive, RTS, CTS
- Configured for High Speed Serial
- The Host USB connection is independent of the state of the FTDI side of the interface
- Host side can communicate with the USB host whether or not the target is even powered up
- Target power on/off doesn't cause a USB disconnect - handy for debug
- Fast operation
- 3.3V or 5V FTDI voltage (order option)
- Transmit/Receive LED Connectors
- On-board LED resistors
- 49x49mm card
- (4) #4 Mounting Holes
Block Diagram
Separate Power Domains
- The OPTOUSB card has two distinct power domains.
- One of the domains is the USB side where the power comes from the USB connector/cable.
- The other power domain is on the TTL side where the power comes from the FTDI connector.
- This is unlike "normal" FTDI interfaces where the USB connection can power the FTDI side.
- This is the purpose of the optical isolation - to isolate the ground of the USB side from the target (FTDI) side.
Connectors
J1 - Mini USB Connector
- Standard USB Mini connector
J2 - Transmit/Receive LED connections
- PUP0 - LED Pullup to USB Power
- TXLED - Transmit LED
- PUP1 - LED Pullup to USB Power
- RXLED - Receive LED
J3 - FTDI Connector
- Signals are references to external system
- GND
- RTS (In to card)
- VCC (3.3V or 5V) - Power must be supplied to this pin
- Receive (Out from card)
- Transmit (In to card)
- CTS (Out from card)
Drivers
- [ FTDI Drivers]
Layout
Transfer Rate Characterization
- LTSpice Simulation results
- 8.6uS per bit = 115,200 baud
Opto-Isolator Drive Circuits
- The card has two independent, isolated power domains
- The USB side is powered from the USB 5V
- The FTDI side is powered from external power
- Connected via header or backfeeding the FTDI connector with voltage
- Voltage is one of either 3.3V or 5V
- 4N25 Optoisolator used between the two sides
- Optoisolator has Vf = 1.3V typical
- Optoisolator has 20% CTR (min)
- Optoisolator can be fed with up to 50 mA of drive current
- Set nominal LED drive current at half (25 mA)
USB to FTDI Path
USB Drive Side
- USB side has MMBT3904 (2N3904) transistor for driving the optoisolator
- Vce(Sat) at 10 mA is 0.2V
- Vce(Sat) at 50 mA is 0.3V
- 5V drops are across transistor (0.3V), optoisolator (1.3V) and series resistor
- Opto voltage is 5 - 0.3 - 1.3 = 3.4V
- Opto drive current needs to be 5x the output current (due to the 20% CTR)
- Assume output current (5 mA)
- Optoisolator LED drive current needs to be 25 mA
- 3.4V / .025A = 136 Ohms (Use 150 Ohms for drive series resistor)
- 150 Ohms will be 22.6 mA drive (good compromise drive current value)
- 22.6 mA drive current at 20% CTR will allow collector current to be 4.5 mA
- Transistor base resistor
- HFE(min)=100 @Ice=10mA, HFE(min) = 60 @Ice=50mA
- Use HFE=60
- 4.7V across resistor, HFE=60, Ice =25mA = 11.3K Ohm resistor
- Drive with 5V, 4.7V across 10K is 0.47 mA
- 0.47mA * 60 = 28.2mA (>25 mA)
- HFE(min)=100 @Ice=10mA, HFE(min) = 60 @Ice=50mA
FTDI-Side Collector Pull-up Resistor
- 25 mA into opto
- CTR(min) = 20%
- ~5mA output current
- Optimal resistor value is at cross-over point where the H-L and L-H prop delays trade-off
- ~1.2K
5V FTDI side Collector Pull-up Resistor
- For 5V, that's about 1.2K
- 5V at 1.2K ohms is 4.1 mA
- 4.5 mA collector current (from above)
- 5V at 1.2K ohms is 4.1 mA
- Use 1.2K pull-up from above
3.3V FTDI side Collector Pull-up Resistor
- 4N25 is not characterized for 3.3V operation in the chart but assume the same current
- Vce(sad) = 0.3V
- 3.3-0.3 = 3V
- 3V / 0.0041A = 731 ohms (680 or 750 are standard 5% values that are near)
- Use 820 ohm pull-up
FTDI to USB Path
- Drive FTDI side from 74AC14
- 74AC14 outputs 24 mA Iol or Ioh
5V Drive from FTDI Side
- 150 Ohm series resistor
- 5V-1.3V = 3.7V
- 3.7V / 150 Ohms = 24mA
- Could drop to 180 Ohms for better margin or double up with 2 drivers/series 300 Ohm resistors in future re-design
USB Side Collector Resistor
- Same as above 5V Collector resistor calculation, 1.2K ohms
3.3V Drive from FTDI Side
- 82 Ohm series resistor
- 3.3V-1.3V = 2.0V
- 2.0V / 82 Ohms = 24mA
- Could drop to 100 Ohms for better margin or double up with 2 drivers/series 180 Ohm resistors in future re-design
Optoisolator Speed-ups
- Optoisolators have asymmetric propagation delays Tplh vs Tphl on their outputs
- At Collector Load Value of 1.2K Ohms
- Tplh = 20 uS
- Tphl = 1.5 uS
- This effect limits signal fidelity
- Ideal would be to have matching Tplh and Tphl values
- These can be balanced by adding a resistor from the output side transistor base to ground
- Hard to find "right" value empirically but checking with a scope it's possible to find a good value
- 18 K Ohms for 5V operation
- 15 K Ohms for 3.3V operation
- Top speed is more than 57.6 kbaud with 4N25M optoisolator
- Note: Testing in loopback mode doubles this problem
Optoisolator Improvements
- 4N25M has a low CTR of 20%
- 4N27 is even worse with CTR of 10% - unusable
- CNY17-4X006 has a much better CTR of 160%-320%
- Tested and works reliably up to 200 kbaud with 18K base resistor (above)
- Could also reduce base current
- Might be able to get FTDI side to run at 3.3V or 5V
Factory Acceptance Test
- Uses dedicated test fixture
- Built on GRID49 card
- Card marked OPTOUSB
- Test fixture features
- 3.3V or 5V power to OptoUSB FTDI TTL level interface
- Tx/Rx LEDs
- Loopback select jumpers
Loopback Select Switches
- TX/RX loopback Switch
- L = Open (Rx pulled up to Vcc)
- R = Connect TX (out) > RX (in)
- Handshake level Switch
- L = Active handshake
- R = Off (Vcc)
- Handshake Switch
- L = Use Center handshake Switch value
- R = Loopback CTS > RTS
Hardware Setup
- Test "Fixture"
- Unit Under Test (UUT)
- Power Supply
- 5V or 3.3V Power Supply (card build option)
- Cabled to 5V Terminal block
- FTDI cable
- From UUT to fixture FTDI jack
- Left side has Black wire
- LEDs cable
- USB Mini cable to PC
Test card
- Run puTTY on PC
- Find port with Device Manager
- Baud rate = 115,200 baud
- Use Hardware handshake RTS/CTS
- Switch settings - Normal operation
- Left switch in right position (loopback data)
- Middle switch in left position (handshake = active/ground)
- Right switch in right position (loopback handshake)
- Type on keyboard and verify it returns data
- Both Green and Blue LEDs should blink
- Switch settings - Test Tx/Rx isolation
- Move left switch to left position
- Type data nothing should come back
- Verify Blue LED only blinks
- Move left switch to right position
- Switch settings - Test RTS/CTS
- Move right switch to left position (handshake controlled by middle jumper)
- Type and characters should return
- Move middle switch to right position (hardware handshake off)
- Type and nothing should go through
- Move middle switch to left position (hardware handshake on)
- Characters that were buffered should come in at once
Revision History
Various incarnations of the card
Rev 5
- Adds test point pads
- Useful for setting TX/RTS Optocoupler output Base resistor values
- Tune for equal low/high pulse widths
- Cleaned up ref des silkscreen locations, increased sizes
Rev 4
- Did not build any
Rev X3
- Fixed silkscreen sizes and relocated
- Adds V/G pads on each side
- Add Rx-, TX+ LEDs J2 marking
- Bigger pads for hand soldering discretes