Small fixes to the booster instruction
Signed-off-by: Egor Savkin <es@m-labs.hk>
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@ -24,7 +24,7 @@ dfu-util -a 0 -s 0x08000000:leave --download booster.bin
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### Basic setup via USB
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1. `nix-shell -p cutecom mosquitto appimage-run`
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2. Install and run `cutecom`: `nix-shell -p cutecom`
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2. Run `cutecom`
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3. Create mosquitto config `mosquitto.conf` with your bound address:
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```
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bind_address 192.168.1.123
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@ -56,12 +56,13 @@ dfu-util -a 0 -s 0x08000000:leave --download booster.bin
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4. Configure oscilloscope for 1M Ohm impedance
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5. Attach attenuator to the Urukul's RF2
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6. `cd py/`
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7. Enable channels: `python -m booster --broker 192.168.1.123 --prefix dt/sinara/booster/xx-xx-xx-xx-xx-xx --channel N tune=0.1`
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8. Use [online calculator](https://www.analog.com/en/design-center/interactive-design-tools/dbconvert.html) for Volts to dBm conversion
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9. Using [booster_template](../extra/booster_template.ods) fill in `y0`, `y1`, `m`, `c`, values using instructions below
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10. Update settings with the adjusted values
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11. Save settings with `python -m booster --broker 192.168.1.123 --prefix dt/sinara/booster/xx-xx-xx-xx-xx-xx --channel N save`
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12. Reboot and check settings are applied
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7. You may also need to download or install python's `gmqtt` and `miniconf`
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8. Enable channels: `python -m booster --broker 192.168.1.123 --prefix dt/sinara/booster/xx-xx-xx-xx-xx-xx --channel N tune=0.1`
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9. Use [online calculator](https://www.analog.com/en/design-center/interactive-design-tools/dbconvert.html) for Volts to dBm conversion
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10. Using [booster_template](../extra/booster_template.ods) fill in `y0`, `y1`, `m`, `c`, values using instructions below
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11. Update settings with the adjusted values
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12. Save settings with `python -m booster --broker 192.168.1.123 --prefix dt/sinara/booster/xx-xx-xx-xx-xx-xx --channel N save`
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13. Reboot and check settings are applied
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### Input power
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@ -81,13 +82,17 @@ extrapolate them for all channels._
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1. Connect Urukul's output (see booster template for exact ports) to the Booster's input
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2. Connect Booster's output to the oscilloscope with load
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3. Measure it's RMS, convert to dBm, put it to the measured cell
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4. Get the output value from telemetry (see booster template for exact path)
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5. Disconnect the Booster's output
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6. Get the reflected value from telemetry
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7. Do steps 1-6 for second Urukul's output
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8. Fill in `slope` and `offset` from settings for output and reflected curves
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9. Do steps 1-8 for every channel
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3. Raise channel's `output_interlock_threshold` to 40
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4. Turn channel's state to `Enabled`
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5. Measure it's RMS, convert to dBm, put it to the measured cell
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6. Get the output value from telemetry (see booster template for exact path)
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7. Disconnect the Booster's output
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8. Get the reflected value from telemetry
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9. Do steps 1-6 for second Urukul's output
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10. Fill in `slope` and `offset` from settings for output and reflected curves
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11. Set channel's `output_interlock_threshold` to 0
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12. Turn channel's state to `Off`
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13. Do steps 1-10 for every channel
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_Note: default setting values are usually the same across channels, so you can extrapolate them for all channels._
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