PyThermostat: Add entry points for runnables

Forms a more convienient interface.
PyThermostat: Add main function to plot.py
2024-11-18 17:51:18 +08:00 · 2024-11-18 17:51:18 +08:00 · 2024-11-18 17:34:39 +08:00 · 2024-11-18 16:22:57 +08:00 · 2024-11-18 14:01:51 +08:00 · 2024-11-18 13:57:54 +08:00
12 changed files with 255 additions and 156 deletions
--- a/README.md
+++ b/README.md
@ -189,31 +189,30 @@ Testing heat flow direction with a low set current is recommended before install
 ### Limits
-Each MAX1968 TEC driver has analog/PWM inputs for setting
+Each channel has maximum value settings, for setting
 output limits.
-Use the `output` command to see current settings and maximum values.
+Use the `output` command to see them.
 | Limit       | Unit    | Description                   |
 | ---         | :---:   | ---                           |
 | `max_v`     | Volts   | Maximum voltage               |
 | `max_i_pos` | Amperes | Maximum positive current      |
 | `max_i_neg` | Amperes | Maximum negative current      |
 | `i_set`     | Amperes | (Not a limit; Open-loop mode) |
 Example: set the maximum voltage of channel 0 to 1.5 V.
 ```
 output 0 max_v 1.5
 ```
-Example: set the maximum negative current of channel 0 to -3 A.
+Example: set the maximum negative current of channel 0 to -2 A.
 ```
-output 0 max_i_neg 3
+output 0 max_i_neg 2
 ```
-Example: set the maximum positive current of channel 1 to 3 A.
+Example: set the maximum positive current of channel 1 to 2 A.
 ```
-output 0 max_i_pos 3
+output 1 max_i_pos 2
 ```
 ### Open-loop mode
--- a/tuning.md
+++ b/tuning.md
@ -13,7 +13,7 @@ When tuning Thermostat PID parameters, it is helpful to view the temperature, PI
 To use the Python real-time plotting utility, run
 ```shell
-python pytec/plot.py
+python pythermostat/plot.py
 ```
 ![default view](./assets/default%20view.png)
@ -44,12 +44,12 @@ Below are some general guidelines for manually tuning PID loops. Note that every
 ## Auto Tuning
-A PID auto tuning utility is provided in the Pytec library. The auto tuning utility drives the the load to a controlled oscillation, observes the ultimate gain and oscillation period and calculates a set of PID parameters.
+A PID auto tuning utility is provided in the PyThermostat library. The auto tuning utility drives the the load to a controlled oscillation, observes the ultimate gain and oscillation period and calculates a set of PID parameters.
 To run the auto tuning utility, run
 ```shell
-python pytec/autotune.py
+python pythermostat/autotune.py
 ```
 After some time, the auto tuning utility will output the auto tuning results, below is a sample output
--- a/flake.nix
+++ b/flake.nix
@ -58,10 +58,10 @@
        auditable = false;
      };
-      pytec = pkgs.python3Packages.buildPythonPackage {
+      pythermostat = pkgs.python3Packages.buildPythonPackage {
-        pname = "pytec";
+        pname = "pythermostat";
        version = "0.0.0";
-        src = "${self}/pytec";
+        src = "${self}/pythermostat";
        propagatedBuildInputs =
          with pkgs.python3Packages; [
@ -72,7 +72,7 @@
    in
    {
      packages.x86_64-linux = {
-        inherit thermostat pytec;
+        inherit thermostat pythermostat;
        default = thermostat;
      };
--- a/pytec/plot.py
+++ b/pytec/plot.py
@ -1,128 +0,0 @@
 import numpy as np
 import matplotlib.pyplot as plt
 import matplotlib.animation as animation
 from threading import Thread, Lock
 from pytec.client import Client
 TIME_WINDOW = 300.0
 tec = Client()
 target_temperature = tec.get_pid()[0]['target']
 print("Channel 0 target temperature: {:.3f}".format(target_temperature))
 class Series:
    def __init__(self, conv=lambda x: x):
        self.conv = conv
        self.x_data = []
        self.y_data = []
    def append(self, x, y):
        self.x_data.append(x)
        self.y_data.append(self.conv(y))
    def clip(self, min_x):
        drop = 0
        while drop < len(self.x_data) and self.x_data[drop] < min_x:
            drop += 1
        self.x_data = self.x_data[drop:]
        self.y_data = self.y_data[drop:]
 series = {
    # 'adc': Series(),
    # 'sens': Series(lambda x: x * 0.0001),
    'temperature': Series(),
    # 'i_set': Series(),
    'pid_output': Series(),
    # 'vref': Series(),
    # 'dac_value': Series(),
    # 'dac_feedback': Series(),
    # 'i_tec': Series(),
    'tec_i': Series(),
    'tec_u_meas': Series(),
    # 'interval': Series(),
 }
 series_lock = Lock()
 quit = False
 def recv_data(tec):
    global last_packet_time
    for data in tec.report_mode():
        ch0 = data[0]
        series_lock.acquire()
        try:
            for k, s in series.items():
                if k in ch0:
                    v = ch0[k]
                    if type(v) is float:
                        s.append(ch0['time'], v)
        finally:
            series_lock.release()
        if quit:
            break
 thread = Thread(target=recv_data, args=(tec,))
 thread.start()
 fig, ax = plt.subplots()
 for k, s in series.items():
    s.plot, = ax.plot([], [], label=k)
 legend = ax.legend()
 def animate(i):
    min_x, max_x, min_y, max_y = None, None, None, None
    series_lock.acquire()
    try:
        for k, s in series.items():
            s.plot.set_data(s.x_data, s.y_data)
            if len(s.y_data) > 0:
                s.plot.set_label("{}: {:.3f}".format(k, s.y_data[-1]))
            if len(s.x_data) > 0:
                min_x_ = min(s.x_data)
                if min_x is None:
                    min_x = min_x_
                else:
                    min_x = min(min_x, min_x_)
                max_x_ = max(s.x_data)
                if max_x is None:
                    max_x = max_x_
                else:
                    max_x = max(max_x, max_x_)
            if len(s.y_data) > 0:
                min_y_ = min(s.y_data)
                if min_y is None:
                    min_y = min_y_
                else:
                    min_y = min(min_y, min_y_)
                max_y_ = max(s.y_data)
                if max_y is None:
                    max_y = max_y_
                else:
                    max_y = max(max_y, max_y_)
        if min_x and max_x - TIME_WINDOW > min_x:
            for s in series.values():
                s.clip(max_x - TIME_WINDOW)
    finally:
        series_lock.release()
    if min_x != max_x:
        ax.set_xlim(min_x, max_x)
    if min_y != max_y:
        margin_y = 0.01 * (max_y - min_y)
        ax.set_ylim(min_y - margin_y, max_y + margin_y)
    global legend
    legend.remove()
    legend = ax.legend()
 ani = animation.FuncAnimation(
    fig, animate, interval=1, blit=False, save_count=50)
 plt.show()
 quit = True
 thread.join()
--- a/pytec/setup.py
+++ b/pytec/setup.py
@ -1,12 +0,0 @@
 from setuptools import setup, find_packages
 setup(
    name="pytec",
    version="0.0",
    author="M-Labs",
    url="https://git.m-labs.hk/M-Labs/thermostat",
    description="Control TEC",
    license="GPLv3",
    install_requires=["setuptools"],
    packages=find_packages(),
 )
--- a/pythermostat/autotune.py
+++ b/pythermostat/autotune.py
@ -3,7 +3,7 @@ import logging
 from collections import deque, namedtuple
 from enum import Enum
-from pytec.client import Client
+from pythermostat.client import Client
 # Based on hirshmann pid-autotune libiary
 # See https://github.com/hirschmann/pid-autotune
--- a/pythermostat/example.py
+++ b/pythermostat/example.py
@ -1,5 +1,5 @@
 import time
-from pytec.client import Client
+from pythermostat.client import Client
 tec = Client() #(host="localhost", port=6667)
 tec.set_param("b-p", 1, "t0", 20)
--- a/pythermostat/plot.py
+++ b/pythermostat/plot.py
@ -0,0 +1,137 @@
 import time
 import numpy as np
 import matplotlib.pyplot as plt
 import matplotlib.animation as animation
 from threading import Thread, Lock
 from pythermostat.client import Client
 def main():
    TIME_WINDOW = 300.0
    tec = Client()
    target_temperature = tec.get_pid()[0]['target']
    print("Channel 0 target temperature: {:.3f}".format(target_temperature))
    class Series:
        def __init__(self, conv=lambda x: x):
            self.conv = conv
            self.x_data = []
            self.y_data = []
        def append(self, x, y):
            self.x_data.append(x)
            self.y_data.append(self.conv(y))
        def clip(self, min_x):
            drop = 0
            while drop < len(self.x_data) and self.x_data[drop] < min_x:
                drop += 1
            self.x_data = self.x_data[drop:]
            self.y_data = self.y_data[drop:]
    series = {
        # 'adc': Series(),
        # 'sens': Series(lambda x: x * 0.0001),
        'temperature': Series(),
        # 'i_set': Series(),
        'pid_output': Series(),
        # 'vref': Series(),
        # 'dac_value': Series(),
        # 'dac_feedback': Series(),
        # 'i_tec': Series(),
        'tec_i': Series(),
        'tec_u_meas': Series(),
        # 'interval': Series(),
    }
    series_lock = Lock()
    quit = False
    def recv_data(tec):
        global last_packet_time
        while True:
            data = tec.get_report()
            ch0 = data[0]
            series_lock.acquire()
            try:
                for k, s in series.items():
                    if k in ch0:
                        v = ch0[k]
                        if type(v) is float:
                            s.append(ch0['time'], v)
            finally:
                series_lock.release()
            if quit:
                break
            time.sleep(0.05)
    thread = Thread(target=recv_data, args=(tec,))
    thread.start()
    fig, ax = plt.subplots()
    for k, s in series.items():
        s.plot, = ax.plot([], [], label=k)
    legend = ax.legend()
    def animate(i):
        min_x, max_x, min_y, max_y = None, None, None, None
        series_lock.acquire()
        try:
            for k, s in series.items():
                s.plot.set_data(s.x_data, s.y_data)
                if len(s.y_data) > 0:
                    s.plot.set_label("{}: {:.3f}".format(k, s.y_data[-1]))
                if len(s.x_data) > 0:
                    min_x_ = min(s.x_data)
                    if min_x is None:
                        min_x = min_x_
                    else:
                        min_x = min(min_x, min_x_)
                    max_x_ = max(s.x_data)
                    if max_x is None:
                        max_x = max_x_
                    else:
                        max_x = max(max_x, max_x_)
                if len(s.y_data) > 0:
                    min_y_ = min(s.y_data)
                    if min_y is None:
                        min_y = min_y_
                    else:
                        min_y = min(min_y, min_y_)
                    max_y_ = max(s.y_data)
                    if max_y is None:
                        max_y = max_y_
                    else:
                        max_y = max(max_y, max_y_)
            if min_x and max_x - TIME_WINDOW > min_x:
                for s in series.values():
                    s.clip(max_x - TIME_WINDOW)
        finally:
            series_lock.release()
        if min_x != max_x:
            ax.set_xlim(min_x, max_x)
        if min_y != max_y:
            margin_y = 0.01 * (max_y - min_y)
            ax.set_ylim(min_y - margin_y, max_y + margin_y)
        nonlocal legend
        legend.remove()
        legend = ax.legend()
    ani = animation.FuncAnimation(
        fig, animate, interval=1, blit=False, save_count=50)
    plt.show()
    quit = True
    thread.join()
 if __name__ == "__main__":
    main()
--- a/pythermostat/pythermostat/init.py
+++ b/pythermostat/pythermostat/init.py
--- a/pythermostat/pythermostat/client.py
+++ b/pythermostat/pythermostat/client.py
--- a/pythermostat/setup.py
+++ b/pythermostat/setup.py
@ -0,0 +1,22 @@
 from setuptools import setup, find_packages
 setup(
    name="pythermostat",
    version="0.0",
    author="M-Labs",
    url="https://git.m-labs.hk/M-Labs/thermostat",
    description="Control TEC",
    license="GPLv3",
    install_requires=["setuptools"],
    packages=find_packages(),
    entry_points={
        "gui_scripts": [
            "thermostat_plot = plot:main",
        ],
        "console_scripts": [
            "thermostat_autotune = autotune:main",
            "thermostat_test = test:main",
        ]
    },
    py_modules=["autotune", "plot", "test"],
 )
--- a/pythermostat/test.py
+++ b/pythermostat/test.py
@ -0,0 +1,81 @@
 import argparse
 from contextlib import contextmanager
 from pythermostat.client import Client
 CHANNELS = 2
 def get_argparser():
    parser = argparse.ArgumentParser(description="Thermostat hardware testing script")
    parser.add_argument("host", metavar="HOST", default="192.168.1.26", nargs="?")
    parser.add_argument("port", metavar="PORT", default=23, nargs="?")
    parser.add_argument(
        "-r",
        "--testing_resistance",
        default=10_000,
        help="Testing resistance value through SENS pin in Ohms",
    )
    parser.add_argument(
        "-d",
        "--deviation",
        default=1,
        help="Allowed deviation of resistance in percentage",
    )
    return parser
 def main():
    args = get_argparser().parse_args()
    min_allowed_resistance = args.testing_resistance * (1 - args.deviation / 100)
    max_allowed_resistance = args.testing_resistance * (1 + args.deviation / 100)
    print(min_allowed_resistance, max_allowed_resistance)
    thermostat = Client(args.host, args.port)
    for channel in range(CHANNELS):
        print(f"Channel {channel} is active")
        print("Checking resistance through SENS input ....", end=" ")
        sens_resistance = thermostat.get_report()[channel]["sens"]
        if sens_resistance is not None:
            print(sens_resistance, "Ω")
            if min_allowed_resistance <= sens_resistance <= max_allowed_resistance:
                print("PASSED")
            else:
                print("FAILED")
        else:
            print("Floating SENS input! Is the channel connected?")
        with preserve_thermostat_output_settings(thermostat, channel):
            test_output_settings = {
                "max_i_pos": 2,
                "max_i_neg": 2,
                "max_v": 4,
                "i_set": 0.1,
                "polarity": "normal",
            }
            for field, value in test_output_settings.items():
                thermostat.set_param("output", channel, field, value)
            input(f"Check if channel {channel} current = 0.1 A, and press ENTER...")
        input(f"Channel {channel} testing done, press ENTER to continue.")
        print()
    print("Testing complete.")
@contextmanager
 def preserve_thermostat_output_settings(client, channel):
    original_output_settings = client.get_output()[channel]
    yield original_output_settings
    for setting in "max_i_pos", "max_i_neg", "max_v", "i_set", "polarity":
        client.set_param("output", channel, setting, original_output_settings[setting])
 if __name__ == "__main__":
    main()
Author	SHA1	Message	Date
atse	ee094241bb	PyThermostat: Add entry points for runnables Forms a more convienient interface.	2024-11-18 17:51:18 +08:00
atse	0ff0dbc3ec	PyThermostat: Add main function to plot.py	2024-11-18 17:51:18 +08:00
atse	4beeec6021	PyThermostat: Remove all references to Pytec	2024-11-18 17:34:39 +08:00
atse	6b8a5f5bb8	Rename the Pytec library to PyThermostat Pytec is a misnomer, as the Thermostat is not limited to just controlling TEC modules. The library also interfaces with and controls the Thermostat itself, and not the TEC module directly. See M-Labs/thermostat#149 (comment)	2024-11-18 16:22:57 +08:00
atse	8dd58b364d	README: Fix limits section	2024-11-18 14:01:51 +08:00
atse	ae0d593139	pytec: Stop using client report mode in plot.py Report mode has been removed from the client, stop using it.	2024-11-18 13:57:54 +08:00
atse	adc25c9b2a	pytec: Add hardware testing script Eases the process of testing the hardware. See #143.	2024-11-18 10:31:56 +08:00