reverted script

This commit is contained in:
Florian Agbuya 2024-09-05 15:54:20 +08:00
parent d799fd0d08
commit e22237e347
5 changed files with 412 additions and 280 deletions

View File

@ -17,6 +17,8 @@
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <https://www.gnu.org/licenses/>.
import mmap
import os
import spidev
from pyfastservo.common import (
@ -31,8 +33,6 @@ from pyfastservo.common import (
AUX_ADC_ADDR,
MAP_MASK,
PAGESIZE,
write_to_memory,
read_from_memory
)
# /dev/spidev1.0 <=> spidev<BUS>.<DEVICE>
@ -44,120 +44,276 @@ AUX_ADC_PORT_A = 2
AUX_ADC_PORT_B = 3
def spi_write(spi, address, value):
spi.xfer2([address, value])
def spi_read(spi, address):
rx_buffer = spi.xfer2([0x80 | address, 0x00])
return rx_buffer[1]
def main_adc_config(spi, test_pattern):
def main_adc_config(test_pattern):
high_word = (test_pattern & 0xFF00) >> 8
low_word = test_pattern & 0xFF
spi_write(spi, 0x00, 0x80) # reset
spi_write(spi, 0x01, 0x20) # REGISTER A1: set to Two's complement Data Format
spi_write(spi, 0x02, 0x15) # REGISTER A2: set to LVDS output, set 4 data lanes and turn on test mode
spi_write(spi, 0x03, high_word) # REGISTER A3: test pattern high word
spi_write(spi, 0x04, low_word) # REGISTER A4: test pattern low word
def main_adc_test_mode(spi, enable):
reg_contents = 0x15 if enable else 0x11 # set to LVDS output, set 4 data lanes and turn on or off test mode
spi_write(spi, 0x02, reg_contents)
def verify_adc_registers(spi, reg_to_check):
for register, expected_value in reg_to_check.items():
value = spi_read(spi, register)
print(f"Spi readback register 0x{register:02x}: 0x{value:02x}")
if value != expected_value:
print(f"Different value read than sent in reg 0x{register:02x}")
def read_frame():
return read_from_memory(ADC_FRAME_ADDR, 1)[0]
def perform_bitslip():
for i in range(4):
current_frame = read_frame()
if current_frame != 0x0C:
print(f"Performing bitslip (iteration: {i}). Current frame: 0x{current_frame:02x}")
write_to_memory(ADC_BITSLIP_ADDR, 1)
else:
print(f"No bitslip required; Current frame: 0x{current_frame:02x}")
return
def find_edge():
prev_frame = read_frame()
transition = False
for tap_delay in range(32):
write_to_memory(ADC_DELAY_ADDR, tap_delay)
current_frame = read_frame()
print(f"Tap delay: {tap_delay}, Current frame: 0x{current_frame:02x}")
if current_frame != prev_frame:
if not transition:
transition = True
else:
final_delay = (tap_delay // 2) + 2
print(f"Edge detected; setting iDelay to: {final_delay}")
write_to_memory(ADC_DELAY_ADDR, final_delay)
return
prev_frame = current_frame
# If no edge detected
final_delay = 11
print(f"No edge detected; setting iDelay to: {final_delay}")
write_to_memory(ADC_DELAY_ADDR, final_delay)
def read_adc_channel(high_addr, low_addr):
return (read_from_memory(high_addr, 1)[0] << 8) | read_from_memory(low_addr, 1)[0]
def print_adc_channels():
adc_ch0 = read_adc_channel(ADC_CH0_HIGH_ADDR, ADC_CH0_LOW_ADDR)
adc_ch1 = read_adc_channel(ADC_CH1_HIGH_ADDR, ADC_CH1_LOW_ADDR)
print(f"Final ADC_CH0: 0x{adc_ch0:04x}")
print(f"Final ADC_CH1: 0x{adc_ch1:04x}")
def enable_adc_afe(ch1_x10=False, ch2_x10=False):
ctrl_value = (ch2_x10 << 1) | ch1_x10
write_to_memory(ADC_AFE_CTRL_ADDR, ctrl_value)
afe_ctrl = read_from_memory(ADC_AFE_CTRL_ADDR, 1)[0]
print(f"ADC_AFE_CTRL: 0x{afe_ctrl:02X}")
return afe_ctrl
def configure_ltc2195():
spi = spidev.SpiDev()
try:
spi.open(MAIN_ADC_BUS, MAIN_ADC_DEVICE)
spi.max_speed_hz = 50000
spi.mode = 0b00 # CPOL = 0 CPHA = 0
spi.cshigh = False
# spi.read0 = False
test_pattern = 0x811F
main_adc_config(spi, test_pattern)
spi_buffer = [0x00, 0x80] # reset
rx_buffer = [0x00, 0x00]
verify_adc_registers(spi, {
0x01: 0x20,
0x02: 0x15,
0x03: (test_pattern & 0xFF00) >> 8,
0x04: test_pattern & 0xFF
})
spi.xfer2(spi_buffer)
# Performing Word Align
perform_bitslip()
find_edge()
print_adc_channels()
# REGISTER A1
spi_buffer = [0x01, 0x20] # set to Two's complement Data Format
spi.xfer2(spi_buffer)
main_adc_test_mode(spi, False)
verify_adc_registers(spi, {0x02: 0x11}) # Verify test mode is off
print_adc_channels()
# read values back
spi_buffer = [0x81, 0x00]
rx_buffer = spi.xfer2(spi_buffer)
print(f"Spi readback register 0x01: 0x{rx_buffer[1]:02x}")
if rx_buffer[1] != 0x20:
print("Different value read than sent in reg 0x02")
enable_adc_afe()
# REGISTER A2
spi_buffer = [
0x02,
0x15,
] # set to LVDS output, set 4 data lanes and turn on test mode
spi.xfer2(spi_buffer)
# read values back
spi_buffer = [0x82, 0x00]
rx_buffer = spi.xfer2(spi_buffer)
print(f"Spi readback register 0x02: 0x{rx_buffer[1]:02x}")
if rx_buffer[1] != 0x15:
print("Different value read than sent in reg 0x02")
# REGISTER A3
# test pattern high word
spi_buffer = [0x03, high_word]
spi.xfer2(spi_buffer)
# read balues back
spi_buffer = [0x83, 0x00]
rx_buffer = spi.xfer2(spi_buffer)
print(f"Spi readback register 0x03: 0x{rx_buffer[1]:02x}")
if rx_buffer[1] != high_word:
print("Different value read than sent in reg 0x03")
# REGISTER A4
# test pattern low word
spi_buffer = [0x04, low_word]
spi.xfer2(spi_buffer)
# read balues back
spi_buffer = [0x84, 0x00]
rx_buffer = spi.xfer2(spi_buffer)
print(f"Spi readback register 0x04: 0x{rx_buffer[1]:02x}")
if rx_buffer[1] != low_word:
print("Different value read than sent in reg 0x04")
finally:
spi.close()
def main_adc_test_mode(enable):
spi = spidev.SpiDev()
try:
spi.open(MAIN_ADC_BUS, MAIN_ADC_DEVICE)
spi.max_speed_hz = 50000
spi.mode = 0b00 # CPOL = 0 CPHA = 0
spi.cshigh = False
# spi.read0 = True
reg_contents = (
0x15 if enable else 0x11
) # set to LVDS output, set 4 data lanes and turn on or off test mode
spi_buffer = [0x02, reg_contents]
spi.xfer2(spi_buffer)
# read values back
spi_buffer = [0x82, 0x00]
rx_buffer = spi.xfer2(spi_buffer)
print(f"Spi readback register 0x02: 0x{rx_buffer[1]:02x}")
if rx_buffer[1] != reg_contents:
print("Different value read than sent in reg 0x02")
finally:
spi.close()
def read_from_memory(address, n_bytes):
assert n_bytes <= 4
addr = address
try:
f = os.open("/dev/mem", os.O_SYNC | os.O_RDWR)
with mmap.mmap(
f,
PAGESIZE,
mmap.MAP_SHARED,
mmap.PROT_READ | mmap.PROT_WRITE,
offset=addr & ~MAP_MASK,
) as mem:
start_addr = addr & MAP_MASK
stop_addr = start_addr + 4
# print(f"addr: 0x{addr:x}\tstart_addr: 0x{start_addr}\tstop_addr: 0x{stop_addr}")
contents = mem[start_addr:stop_addr]
read_value = list(contents)[:n_bytes]
# print("Read value: ", read_value)
finally:
os.close(f)
return read_value
def write_to_memory(address, value):
value_bytes = value.to_bytes(4, "little")
addr = address
try:
f = os.open("/dev/mem", os.O_SYNC | os.O_RDWR)
with mmap.mmap(
f,
PAGESIZE,
mmap.MAP_SHARED,
mmap.PROT_READ | mmap.PROT_WRITE,
offset=addr & ~MAP_MASK,
) as mem:
start_addr = addr & MAP_MASK
stop_addr = start_addr + 4
# print(f"addr: 0x{addr:x}\tstart_addr: 0x{start_addr}\tstop_addr: 0x{stop_addr}")
mem[start_addr:stop_addr] = value_bytes
contents = mem[start_addr:stop_addr]
# print("Read value: ", list(contents), " written value: ", list(value_bytes))
finally:
os.close(f)
def word_align():
value = 0
edge_detected = False
transition = False
tap_delay = 0
for i in range(4):
current_frame = read_from_memory(ADC_FRAME_ADDR, 1)[0]
if current_frame != 0x0C:
print(
f"Performing bitslip (bitslip iteration: {i}). Reason: current_frame is 0x{current_frame:02x} instead of 0x0C"
)
write_to_memory(ADC_BITSLIP_ADDR, 1)
else:
print(f"No bitslip required; Currernt frame = 0x{current_frame:02x}")
break
current_frame = read_from_memory(ADC_FRAME_ADDR, 1)[0]
prev_frame = current_frame
for i in range(32):
write_to_memory(ADC_DELAY_ADDR, tap_delay)
if edge_detected == 1:
break
current_frame = read_from_memory(ADC_FRAME_ADDR, 1)[0]
print(f"Tap delay: {tap_delay}")
print(f"Current frame: 0x{current_frame:02x}")
if current_frame == prev_frame:
tap_delay += 1
elif not transition:
tap_delay += 1
transition = True
elif transition:
tap_delay = i // 2
edge_detected = True
prev_frame = current_frame
if not edge_detected:
tap_delay = 11 # empirically tested to work best
write_to_memory(ADC_DELAY_ADDR, tap_delay)
print(f"No edge detected; setting iDelay to: {tap_delay}")
if edge_detected:
write_to_memory(ADC_DELAY_ADDR, tap_delay + 2)
print(f"Edge detected; setting iDelay to (tap_delay + 2): {tap_delay} + 2")
adc_ch0 = read_from_memory(ADC_CH0_HIGH_ADDR, 4)
print(f"ADC_CH0: 0x{adc_ch0}")
adc_ch0 = (read_from_memory(ADC_CH0_HIGH_ADDR, 1)[0] << 8) | read_from_memory(
ADC_CH0_LOW_ADDR, 1
)[0]
adc_ch1 = (read_from_memory(ADC_CH1_HIGH_ADDR, 1)[0] << 8) | read_from_memory(
ADC_CH1_LOW_ADDR, 1
)[0]
print(f"Final ADC_CH0: 0x{adc_ch0:04x}")
print(f"Final ADC_CH1: 0x{adc_ch1:04x}")
def modify_bit(original_value, position, bit_value):
mask = 1 << position
return (original_value & ~mask) | (bit_value << position)
def adc_aux_config():
# MSB to LSB
# | RANGE | ADDR [2:0] | DIFF |
# DIFF = 0 => configure as single ended (it is negated in gateware)
# RANGE = 0 => configure as 0-2.5 Vref
to_write = 0b00000
write_to_memory(AUX_ADC_ADDR, to_write)
def adc_aux_read(port, type, pin):
# port:
# 1 - port A
# 2 - port B
# type:
# 0 - single-ended
# 1 - differential
# pin:
# 0b000 - VA1/VB1
# 0b001 - VA2/VB2
# 0b010 - VA3/VB3
# 0b011 - VA4/VB4
assert type in (0, 1)
assert port in (1, 2)
write_buffer = [0, 0]
read_buffer = [0, 0]
aux_config_reg = read_from_memory(AUX_ADC_ADDR, 1)[0]
aux_config = (aux_config_reg & 0b10001) | pin << 1
write_to_memory(AUX_ADC_ADDR, aux_config)
spi = spidev.SpiDev()
try:
spi.open(1, 3) # AUX ADC 1?
spi.max_speed_hz = 5000
spi.mode = 0b00
spi.cshigh = False
read_buffer = spi.xfer2(write_buffer)
mu_voltage = read_buffer[0] << 8 | read_buffer[1] >> 2
print(f"MU_voltage: 0x{mu_voltage:04X}")
print(f"Read_buffer[0]: 0x{read_buffer[0]:02X}")
print(f"Read_buffer[1]: 0x{read_buffer[1]:02X}")
return mu_voltage * 2.5 / 4096
finally:
spi.close()
def main():
main_adc_config(0x811F)
word_align()
main_adc_test_mode(False)
write_to_memory(ADC_AFE_CTRL_ADDR, 0b1100) # {-, -, ch2_X10, ch1_X10}
print(read_from_memory(ADC_AFE_CTRL_ADDR, 1)[0])
if __name__ == "__main__":
configure_ltc2195()
main()

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@ -17,9 +17,6 @@
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <https://www.gnu.org/licenses/>.
import os
import mmap
CSR_SIZE = 0x800
MAP_SIZE = 0x1000
MAP_MASK = 0xFFF
@ -74,47 +71,4 @@ CTRL_ADDR = DAC_BASE_ADDR + CTRL_OFFSET
CH0_HIGH_WORD_ADDR = DAC_BASE_ADDR + CH0_HIGH_WORD_OFFSET
CH0_LOW_WORD_ADDR = DAC_BASE_ADDR + CH0_LOW_WORD_OFFSET
CH1_HIGH_WORD_ADDR = DAC_BASE_ADDR + CH1_HIGH_WORD_OFFSET
CH1_LOW_WORD_ADDR = DAC_BASE_ADDR + CH1_LOW_WORD_OFFSET
def read_from_memory(address, n_bytes):
assert n_bytes <= 4
addr = address
try:
f = os.open("/dev/mem", os.O_SYNC | os.O_RDWR)
with mmap.mmap(
f,
PAGESIZE,
mmap.MAP_SHARED,
mmap.PROT_READ | mmap.PROT_WRITE,
offset=addr & ~MAP_MASK,
) as mem:
start_addr = addr & MAP_MASK
stop_addr = start_addr + 4
contents = mem[start_addr:stop_addr]
read_value = list(contents)[:n_bytes]
finally:
os.close(f)
return read_value
def write_to_memory(address, value):
value_bytes = value.to_bytes(4, "little")
addr = address
try:
f = os.open("/dev/mem", os.O_SYNC | os.O_RDWR)
with mmap.mmap(
f,
PAGESIZE,
mmap.MAP_SHARED,
mmap.PROT_READ | mmap.PROT_WRITE,
offset=addr & ~MAP_MASK,
) as mem:
start_addr = addr & MAP_MASK
stop_addr = start_addr + 4
mem[start_addr:stop_addr] = value_bytes
contents = mem[start_addr:stop_addr]
finally:
os.close(f)
CH1_LOW_WORD_ADDR = DAC_BASE_ADDR + CH1_LOW_WORD_OFFSET

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@ -17,7 +17,8 @@
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <https://www.gnu.org/licenses/>.
import time
import mmap
import os
import spidev
from pyfastservo.common import (
@ -28,58 +29,108 @@ from pyfastservo.common import (
CTRL_ADDR,
MAP_MASK,
PAGESIZE,
write_to_memory,
read_from_memory
)
# /dev/spidev2.0 <=> spidev<BUS>.<DEVICE>
MAIN_DAC_BUS = 2
MAIN_DAC_DEVICE = 0
DAC_VERSION = 0x0A
def spi_write(spi, address, value):
spi.xfer2([address, value])
def main_dac_init():
spi = spidev.SpiDev()
def spi_read(spi, address):
rx_buffer = spi.xfer2([0x80 | address, 0x00])
return rx_buffer[1]
try:
spi.open(MAIN_DAC_BUS, MAIN_DAC_DEVICE)
spi.max_speed_hz = 5000
spi.mode = 0b00 # CPOL = 0 CPHA = 0
spi.cshigh = False
def hard_reset(spi):
spi_write(spi, 0x00, 0x20) # Software reset
spi_write(spi, 0x00, 0x00) # Release software reset
spi_read(spi, 0x00) # Read reset address (necessary for reset to take effect)
spi_buffer = [0x00, 0x10] # software reset
spi.xfer2(spi_buffer)
def check_version(spi):
version = spi_read(spi, 0x1F)
print(f"DAC version: 0x{version:02X}")
return version == DAC_VERSION
spi_buffer = [0x00, 0x00] # release software reset
spi.xfer2(spi_buffer)
def configure_dac(spi):
power_down_reg = spi_read(spi, 0x01)
spi_write(spi, 0x01, power_down_reg & ~(1 << 0)) # Clear EXTREF bit for internal reference
spi_write(spi, 0x0D, 0x00) # Set RREF to 10 kΩ for 1.0V reference
spi_write(spi, 0x04, 0xA0) # Enable on-chip IRSET (1.6 kΩ for 20mA output)
spi_write(spi, 0x07, 0xA0) # Enable on-chip QRSET (1.6 kΩ for 20mA output)
spi_write(spi, 0x05, 0x00) # Disable internal IRCML
spi_write(spi, 0x08, 0x00) # Disable internal QRCML
spi_write(spi, 0x02, 0xB4) # Enable 2's complement, LVDS interface, 4 LVDS lanes
spi_buffer = [
0x80,
0x00,
] # for some reason it is needed to read the reset address for reset to actually reset
rx_buffer = spi.xfer2(spi_buffer)
def dac_self_calibration(spi):
spi_write(spi, 0x12, 0x00) # Reset calibration status
spi_write(spi, 0x0E, 0x08) # Enable calibration clock, default divide ratio
spi_write(spi, 0x0E, 0x38) # CALSELI = 1, CALSELQ = 1, CALCLK = 1
spi_write(spi, 0x12, 0x10) # Set CALEN bit
spi_buffer = [0x9F, 0x00] # hardware version
rx_buffer = spi.xfer2(spi_buffer)
if rx_buffer[1] != DAC_VERSION:
print(f"Unrecognized device: 0x{rx_buffer[1]:02X}")
while True:
status = spi_read(spi, 0x0F)
if status & 0xC0 == 0xC0: # Both CALSTATI and CALSTATQ are 1
break
time.sleep(0.01)
print("=== Contents of spi buffer after DAC VERSION read back: ===")
print(f"0x{rx_buffer[0]:02X}{rx_buffer[1]:02X}")
spi_buffer = [0x82, 00]
rx_buffer = spi.xfer2(spi_buffer)
print(f"0x{rx_buffer[0]:02X}{rx_buffer[1]:02X}")
# set to 2's complement and I to be first of pair on data input pads
spi_buffer = [0x02, 0xB4]
rx_buffer = spi.xfer2(spi_buffer)
spi_buffer = [0x82, 00]
rx_buffer = spi.xfer2(spi_buffer)
print(f"0x{rx_buffer[0]:02X}{rx_buffer[1]:02X}")
for i in range(10):
spi_buffer = [0x94, 0x00]
rx_buffer = spi.xfer2(spi_buffer)
print(f"0x{rx_buffer[0]:02X}{rx_buffer[1]:02X}")
finally:
spi.close()
def read_from_memory(address, n_bytes):
assert n_bytes <= 4
addr = address
try:
f = os.open("/dev/mem", os.O_SYNC | os.O_RDWR)
with mmap.mmap(
f,
PAGESIZE,
mmap.MAP_SHARED,
mmap.PROT_READ | mmap.PROT_WRITE,
offset=addr & ~MAP_MASK,
) as mem:
start_addr = addr & MAP_MASK
stop_addr = start_addr + 4
# print(f"addr: 0x{addr:x}\tstart_addr: 0x{start_addr}\tstop_addr: 0x{stop_addr}")
contents = mem[start_addr:stop_addr]
read_value = list(contents)[:n_bytes]
finally:
os.close(f)
return read_value
def write_to_memory(address, value):
value_bytes = value.to_bytes(4, "little")
addr = address
try:
f = os.open("/dev/mem", os.O_SYNC | os.O_RDWR)
with mmap.mmap(
f,
PAGESIZE,
mmap.MAP_SHARED,
mmap.PROT_READ | mmap.PROT_WRITE,
offset=addr & ~MAP_MASK,
) as mem:
start_addr = addr & MAP_MASK
stop_addr = start_addr + 4
mem[start_addr:stop_addr] = value_bytes
contents = mem[start_addr:stop_addr]
finally:
os.close(f)
spi_write(spi, 0x12, 0x00) # Clear calibration bits
spi_write(spi, 0x0E, 0x30) # Keep CALSELI and CALSELQ set, clear CALCLK
print("DAC self-calibration completed")
def manual_override(enable=True):
reg_contents = read_from_memory(CTRL_ADDR, 1)[0]
@ -87,6 +138,7 @@ def manual_override(enable=True):
to_write = reg_contents | 0b1 if enable else reg_contents & 0b110
write_to_memory(CTRL_ADDR, to_write)
def power_down(channel, power_down=True):
assert channel in (0, 1)
@ -100,49 +152,31 @@ def power_down(channel, power_down=True):
reg_contents = read_from_memory(CTRL_ADDR, 1)[0]
print(f"REG contents: 0b{reg_contents:03b}")
def set_dac_output(value):
value = min(value, 0x3FFF)
low_word = value & 0xFF
high_word = (value >> 8) & 0x3F
write_to_memory(CH0_HIGH_WORD_ADDR, high_word)
write_to_memory(CH0_LOW_WORD_ADDR, low_word)
write_to_memory(CH1_HIGH_WORD_ADDR, high_word)
write_to_memory(CH1_LOW_WORD_ADDR, low_word)
print(f"DAC output set to: 0x{value:04X}")
def write_sample(channel, sample):
assert channel in (0, 1)
if channel == 0:
addresses = [CH0_HIGH_WORD_ADDR, CH0_LOW_WORD_ADDR]
else:
addresses = [CH1_HIGH_WORD_ADDR, CH1_LOW_WORD_ADDR]
def configure_ad9117():
spi = spidev.SpiDev()
spi.open(MAIN_DAC_BUS, MAIN_DAC_DEVICE)
spi.max_speed_hz = 5000
spi.mode = 0b00 # CPOL = 0 CPHA = 0
spi.cshigh = False
low_word_value = sample & 0xFF
high_word_value = (sample >> 8) & 0x3F
values = [high_word_value, low_word_value]
for addr, value in zip(addresses, values):
write_to_memory(addr, value)
try:
hard_reset(spi)
if not check_version(spi):
print("Unrecognized DAC version")
return False
configure_dac(spi)
# dac_self_calibration(spi)
def write_ramp():
signal = [i for i in range(16384)]
# Enable DAC outputs
spi_write(spi, 0x01, spi_read(spi, 0x01) & ~((1 << 4) | (1 << 3)))
power_down(0, False)
power_down(1, False)
manual_override(True)
print("AD9117 configuration completed successfully")
return True
except Exception as e:
print(f"Error configuring AD9117: {e}")
return False
finally:
spi.close()
for value in signal:
write_sample(0, value)
def main():
main_dac_init()
power_down(0, False)
power_down(1, False)
if __name__ == "__main__":
configure_ad9117()
main()

View File

@ -21,8 +21,8 @@ from pyfastservo import adc, si5340, dac
def main():
si5340.configure_si5340()
adc.configure_ltc2195()
dac.configure_ad9117()
adc.main()
dac.main()
if __name__ == "__main__":
main()

View File

@ -1,60 +1,48 @@
import time
from pyfastservo import adc, dac
from pyfastservo.common import (
ADC_CH0_HIGH_ADDR, ADC_CH0_LOW_ADDR,
ADC_CH1_HIGH_ADDR, ADC_CH1_LOW_ADDR,
CH0_HIGH_WORD_ADDR, CH0_LOW_WORD_ADDR,
CH1_HIGH_WORD_ADDR, CH1_LOW_WORD_ADDR,
read_from_memory, write_to_memory
# This file is part of Fast Servo Software Package.
#
# Copyright (C) 2023 Jakub Matyas
# Warsaw University of Technology <jakubk.m@gmail.com>
# SPDX-License-Identifier: GPL-3.0-or-later
from pyfastservo.dac import (
CH0_HIGH_WORD_ADDR,
CH0_LOW_WORD_ADDR,
CH1_HIGH_WORD_ADDR,
CH1_LOW_WORD_ADDR,
write_sample,
manual_override,
read_from_memory as dac_read_from_memory
)
from pyfastservo.adc import (
ADC_CH0_HIGH_ADDR,
ADC_CH0_LOW_ADDR,
ADC_CH1_HIGH_ADDR,
ADC_CH1_LOW_ADDR,
read_from_memory as adc_read_from_memory
)
def read_adc(channel):
if channel == 0:
return adc.read_adc_channel(ADC_CH0_HIGH_ADDR, ADC_CH0_LOW_ADDR)
elif channel == 1:
return adc.read_adc_channel(ADC_CH1_HIGH_ADDR, ADC_CH1_LOW_ADDR)
else:
raise ValueError("Invalid ADC channel")
def write_dac(value):
dac.set_dac_output(value)
def read_dac(channel):
if channel == 0:
high_word = read_from_memory(CH0_HIGH_WORD_ADDR, 1)[0]
low_word = read_from_memory(CH0_LOW_WORD_ADDR, 1)[0]
elif channel == 1:
high_word = read_from_memory(CH1_HIGH_WORD_ADDR, 1)[0]
low_word = read_from_memory(CH1_LOW_WORD_ADDR, 1)[0]
else:
raise ValueError("Invalid DAC channel")
return (high_word << 8) | low_word
def perform_loopback_test(test_value):
print(f"\nSetting DAC output to {test_value}...")
write_dac(test_value)
time.sleep(0.1) # Allow time for the signal to stabilize
for channel in [0, 1]:
print(f"\nTesting Channel {channel}")
print(f"Reading ADC CH{channel} value...")
adc_value = read_adc(channel)
print(f"ADC CH{channel} readback: {adc_value}")
print(f"Reading DAC CH{channel} value...")
dac_value = read_dac(channel)
print(f"DAC CH{channel} readback: {dac_value}")
if abs(test_value - adc_value) <= 2 and abs(test_value - dac_value) <= 2:
print(f"Loopback test for Channel {channel} PASSED!")
else:
print(f"Loopback test for Channel {channel} FAILED!")
print(f"Expected: {test_value}, ADC: {adc_value}, DAC: {dac_value}")
#
def main():
test_value = 0x0FFF # Mid-range value (4095 in decimal)
perform_loopback_test(test_value)
# Apply manual override for DAC
manual_override(True)
# Write constant value to DAC channels
constant_value = 0x1FFF
write_sample(0, constant_value)
write_sample(1, constant_value)
# Verify DAC register values
dac_ch0 = (dac_read_from_memory(CH0_HIGH_WORD_ADDR, 1)[0] << 8) | dac_read_from_memory(CH0_LOW_WORD_ADDR, 1)[0]
dac_ch1 = (dac_read_from_memory(CH1_HIGH_WORD_ADDR, 1)[0] << 8) | dac_read_from_memory(CH1_LOW_WORD_ADDR, 1)[0]
print(f"DAC CH0: 0x{dac_ch0:04X}")
print(f"DAC CH1: 0x{dac_ch1:04X}")
# Read ADC values
adc_ch0 = (adc_read_from_memory(ADC_CH0_HIGH_ADDR, 1)[0] << 8) | adc_read_from_memory(ADC_CH0_LOW_ADDR, 1)[0]
adc_ch1 = (adc_read_from_memory(ADC_CH1_HIGH_ADDR, 1)[0] << 8) | adc_read_from_memory(ADC_CH1_LOW_ADDR, 1)[0]
print(f"ADC CH0: 0x{adc_ch0:04X}")
print(f"ADC CH1: 0x{adc_ch1:04X}")
if __name__ == "__main__":
main()