Minnow is a tool for using DAM (Debug Accessory Mode), providing an interface to SWD or JTAG and/or UART from the device. It expands upon this concept to include a USB-UART and some utility for use within test rigs. It could be considered SWD over DAM with a sprinkling of USB cereal - unlike usb-cereal it does not use the Chromebook UART mapping in favour of maintaining USB-C rotational symmetry.
- Enables and interfaces USB DAM configured in image below; Full SWD or JTAG over USB-C.
- Provides board designer the option of using RX+ for NRST/RXD and RX- for SWO/TXD - either single-wire trace communication (RTT) or UART.
- Four configurable GPIO on FT230 for test rig control of UUT: power enable; RX pin control; reset.
- TagConnect TC2030 and ARM 10-pin header to debugger.
- USB pass-through or FT230 USB UART to device.
- VTARGET reference from device or external.
- Maintains USB-C rotational symmetry.
- Alternate Mode 3.1+ can still be used in the main application with normal hosts.
Original reference modified to include option of UART.
The latest release is full tested and I have PCBAs for purchase:
- Purchase from my shop.
- Purchase from Tindie.
- Since it's a development tool, it uses 0603 so can be easily assembled/modified by hand.
Minnow connected to the USB DAM example test board - this would be integrated to a target in practice
Here is a quick video showing basic usage: https://youtu.be/QQiKsJ13bL0
Note the target device must be designed to enable DAM mode following the USB specification and Minnow DAM USB-C connections. I have made an example board that does this, see below.
If a cable is required between Minnow and the device (TS), the cable needs to be a complete USB-C extension cable with all Alternate Mode wires. USB 3.1+, DisplayPort, Thunderbolt and HDMI rated cables should include these. Here are a couple: usb-c-extension-cable-for-raspberry-pi-4 or Tripp Lite U421-20N-G2.
USB-C extension cables are not technically specification compliant but one is required for DAM because no compliant male-male cable will supply both CC1 and CC2 between the the DTS and TS. See USB Type-C: B.2.3.1.
I learnt this the hard way: R1 Minnow had a receptacle for both the host and device and no cable worked to enable USB DAM using the CC pull-ups with logic AND. As the specification says, this is why a direct plug is required for USB DAM mode and why Minnow R2 now has one.
The cable to the host can be a USB 2.0.
I've included an example design for the device end: './example-dev/usb-dam.kicad_pro' pdf. It can be used for testing and as a foundation for a project with DAM. There are clearly alternative design choices that can be made based on the requirements of the device but it is a good starting point. The layout was done in haste as a means to test the Minnow board!
Essentially the target must detect when the CC lines are pulled up with the values specified in the USB specification (500mA @5V 10kΩ on CC1 and 22kΩ on CC2). Because the CC lines might also have 5k1 pull-downs, a potential divider is created:
- CC1: Host 22kΩ pull-up to 5V and device 5.1kΩ pull-down = 0.9V
- CC2: Host 10kΩ pull-up to 5V and device 5.1kΩ pull-down = 1.7V
The example board uses two op-amps configured as non-inverting amplifiers to buffer this to a logic AND, which enables a 4-channel switch to connect the debug lines to the Alternate Mode pins.
USB host to device; device powered; full SWD on debug headers; VCCIO from VTARGET.
By default, VCCIO for the FT230 is supplied from VTARGET (< 10 uA current demand from logic gates) to ensure the same logic level as the target. VCCIO controls the logic level for the GPIO and UART. Cut JP5 1-2 and link 2-3 to use JP6 source - default 3V3 1-2, 2-3 VEXT for external source (1V8 for example). If using a VCCIO source less than 3V3, one should take the LEDs out of circuit by removing R1 and R2 as they are pulled to 3V3.
Logic level is sourced from VCCIO; VTARGET from the device by default. If no device is attached, there is no logic level and so nothing to sink the LEDs or send UART for that matter. Consider this a feature not a bug since they don't blink if nothing is output/listening 🙂. To change this, VCCIO can be self-supplied with JP5 2-3 - see 'VCCIO Selection'.
One must switch SW1:1 ON to enable USB -> FT230 rather than device. Also be aware that the default configuration VCCIO is supplied from the device and without this there is no logic on the UART/GPIO pins. See 'VCCIO Selection'. It's the reason I didn't include a GPIO to the device power since it would not work without an external VCCIO source.
First switch the VCCIO source from VTARGET - see 'VCCIO Selection' - as logic will be required without the device. Add the resistor R15 (680R or anthing to protect GPIO) to link CB3 to the load switch. It's active LOW.
The cable to the device is probably not a USB 3.1+ (or a bad one) and does not include the alternate mode pins. Use a cable tester to continuity test the cable or find a better one! See 'Cable'.
See ftx-prog, the main FTDI utilities page or the pyftdi module. The GPIO pins can be changed at runtime or non-volatile with the EEPROM - see './power-gpio.py' as an example of toggling power to the device.
I personally use the 'ftconf.py' script as part of pyftdi to provision new devices using './provision.py'.