shuttler: add AFE drivers

2023-09-13 16:46:51 -07:00 · 2023-09-13 16:46:51 -07:00 · eb08c55abe
parent 67b6588d95
commit eb08c55abe
1 changed files with 145 additions and 0 deletions
--- a/artiq/coredevice/shuttler.py
+++ b/artiq/coredevice/shuttler.py
@ -3,6 +3,14 @@ import numpy
 from artiq.language.core import *
 from artiq.language.types import *
 from artiq.coredevice.rtio import rtio_output, rtio_input_data
 from artiq.coredevice import spi2 as spi
 from artiq.language.units import us
@portable
 def shuttler_volt_to_mu(volt):
    # TODO: Check arg, raise exception if exceeds shuttler limit
    return int(round((1 << 14) * (volt / 20.0))) & 0x3fff
 class Config:
@ -116,3 +124,140 @@ class Trigger:
    @kernel
    def trigger(self, trig_out):
        rtio_output(self.target_o, trig_out)
 RELAY_SPI_CONFIG = (0*spi.SPI_OFFLINE | 1*spi.SPI_END |
                    0*spi.SPI_INPUT | 0*spi.SPI_CS_POLARITY |
                    0*spi.SPI_CLK_POLARITY | 0*spi.SPI_CLK_PHASE |
                    0*spi.SPI_LSB_FIRST | 0*spi.SPI_HALF_DUPLEX)
 SPI_CS_RELAY = 1 << 0
 SPI_CS_LED = 1 << 1
 SPI_DIV = 4
 ADC_SPI_CONFIG = (0*spi.SPI_OFFLINE | 0*spi.SPI_END |
                  0*spi.SPI_INPUT | 0*spi.SPI_CS_POLARITY |
                  1*spi.SPI_CLK_POLARITY | 1*spi.SPI_CLK_PHASE |
                  0*spi.SPI_LSB_FIRST | 0*spi.SPI_HALF_DUPLEX)
 ADC_CS = 1
 ADC_SPI_DIV = 32
 class Relay:
    kernel_invariant = {"core", "bus"}
    def __init__(self, dmgr, spi_device, core_device="core"):
        self.core = dmgr.get(core_device)
        self.bus = dmgr.get(spi_device)
    @kernel
    def init(self):
        self.bus.set_config_mu(
            RELAY_SPI_CONFIG, 16, SPI_DIV, SPI_CS_RELAY | SPI_CS_LED)
    @kernel
    def set_led(self, leds: TInt32):
        self.bus.write(leds << 16)
 class ADC:
    kernel_invariant = {"core", "bus"}
    def __init__(self, dmgr, spi_device, core_device="core"):
        self.core = dmgr.get(core_device)
        self.bus = dmgr.get(spi_device)
    @kernel
    def read_id(self) -> TInt32:
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_END | spi.SPI_INPUT,
            24, ADC_SPI_DIV, ADC_CS)
        self.bus.write(0x47 << 24)
        return (self.bus.read() & 0xFFFF)
    @kernel
    def read_ch(self, channel: TInt32) -> TFloat:
        # Always configure Profile 0
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_END, 24, ADC_SPI_DIV, ADC_CS)
        self.bus.write(0x10 << 24 | (0x8000 | ((channel * 2 + 1) << 4)) << 8)
        # Configure Setup 0
        # Input buffer must be enabled to use REF pins correctly
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_END, 24, ADC_SPI_DIV, ADC_CS)
        self.bus.write((0x20 << 24) | (0x1300 << 8))
        # Trigger single conversion
        self.bus.set_config_mu(
            ADC_SPI_CONFIG, 24, ADC_SPI_DIV, ADC_CS)
        self.bus.write((0x01 << 24) | (0x8010 << 8))
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_INPUT, 16, ADC_SPI_DIV, ADC_CS)
        self.bus.write(0x40 << 24)
        while self.bus.read() & 0x80:
            delay(10*us)
            self.bus.write(0x40 << 24)
        delay(10*us)
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_END | spi.SPI_INPUT,
            32, ADC_SPI_DIV, ADC_CS)
        self.bus.write(0x44 << 24)
        adc_code = self.bus.read() & 0xFFFFFF
        return ((adc_code / (1 << 23)) - 1) * 2.5 / 0.1
    @kernel
    def calibrate(self, volts, trigger, config, samples=[-5.0, 0.0, 5.0]):
        assert len(volts) == 16
        assert len(samples) > 1
        measurements = [0.0] * len(samples)
        for ch in range(16):
            # Find the average slope rate and offset
            for i in range(len(samples)):
                self.core.break_realtime()
                volts[ch].set_waveform(
                    shuttler_volt_to_mu(samples[i]), 0, 0, 0)
                trigger.trigger(1 << ch)
                delay(1*us)
                measurements[i] = self.read_ch(ch ^ 1)
            # Find the average output slope
            print(measurements)
            slope_sum = 0.0
            for i in range(len(samples) - 1):
                slope_sum += (measurements[i+1] - measurements[i])/(samples[i+1] - samples[i])
            slope_avg = slope_sum / (len(samples) - 1)
            print(slope_avg)
            print("Suitable gain in Shuttler:")
            gain_code = int32(1 / slope_avg * (2 ** 16)) & 0xffff
            print(gain_code)
            # Scale the measurements by 1/slope, find average offset
            offset_sum = 0.0
            for i in range(len(samples)):
                offset_sum += (measurements[i] / slope_avg) - samples[i]
            offset_avg = offset_sum / len(samples)
            print(offset_avg)
            print("Suitable offset in Shuttler:")
            offset_code = shuttler_volt_to_mu(-offset_avg)
            print(offset_code)
            self.core.break_realtime()
            config.set_gain(ch, gain_code)
            delay_mu(int64(self.core.ref_multiplier))
            assert config.get_gain(ch) == gain_code
            self.core.break_realtime()
            config.set_offset(ch, offset_code)
            delay_mu(int64(self.core.ref_multiplier))
            assert config.get_offset(ch) == offset_code