--- /dev/null
+#!/usr/bin/python
+
+import os,sys
+
+class PID3:
+ """From http://www.chrismarion.net/index.php?option=com_content&view=article&id=166:adventures-in-pid-control&catid=44:robotics&Itemid=240"""
+ def __init__(self, Kp, Ki, Kd):
+ self.Kp = Kp
+ self.Ki = Ki
+ self.Kd = Kd
+ self.initialize()
+ def SetKp(self, Kp):
+ self.Kp = Kp
+ def SetKi(self, Ki):
+ self.Ki = Ki
+ def SetKd(self, Kd):
+ self.Kd = Kd
+ def SetPoint(self, point):
+ self.setpoint = point
+ def SetPrevErr(self, preverr):
+ self.prev_err = preverr
+ def initialize(self):
+ self.setpoint = 0
+ self.currtm = 0 #time.time()
+ self.prevtm = self.currtm
+ self.prev_err = 0
+ self.Cp = 0
+ self.Ci = 0
+ self.Cd = 0
+ def update(self, current_time, current_value):
+ """ Performs a PID computation and returns a control value based on the
+ elapased time (dt) and the error signal from a summing junction. """
+ self.currtm = current_time #get t
+ error = self.setpoint - current_value
+ dt = self.currtm - self.prevtm #get delta t
+ de = error - self.prev_err #get delta error
+ self.Cp = self.Kp * error #proportional term
+ self.Ci += error * dt #integral term
+ self.Cd = 0
+ if dt > 0: #no div by zero
+ self.Cd = de/dt #derivative term
+ self.prevtm = self.currtm #save t for next pass
+ self.prev_err = error #save t-1 error
+ return self.Cp + (self.Ki * self.Ci) + (self.Kd * self.Cd)
+
+
+class PID:
+ """Discrete PID control"""
+ def __init__(self, P=2.0, I=0.0, D=1.0, Derivator=0, Integrator=0,
+ Integrator_max=0, Integrator_min=5000):
+ self.Kp = P
+ self.Ki = I
+ self.Kd = D
+ self.Derivator = Derivator
+ self.Integrator = 0
+ self.Integrator_max = Integrator_max
+ self.Integrator_min = Integrator_min
+ self.set_point = 0.0
+
+ def update(self, current_value):
+ """Calculate PID output value for given input"""
+ error = self.set_point - current_value
+ P = self.Kp * error
+ D = self.Kd * (error - self.Derivator)
+ self.Derivator = error
+ self.Integrator += error
+ if self.Integrator > self.Integrator_max:
+ self.Integrator = self.Integrator_max
+ elif self.Integrator < self.Integrator_min:
+ self.Integrator = self.Integrator_min
+ I = self.Integrator * self.Ki
+ return P + I + D
+
+ @property
+ def point(self):
+ return self.set_point
+ @point.setter
+ def point(self, set_value):
+ """Initialize the setpoint of the PID"""
+ self.set_point = value
+ self.Integrator = 0
+ self.Derivator = 0
+ @property
+ def Kp(self):
+ return self.Kp
+ @Kp.setter
+ def Kp(self, value):
+ self.Kp = value
+ @property
+ def Ki(self):
+ return self.Ki
+ @Ki.setter
+ def Ki(self, value):
+ self.Ki = value
+ @property
+ def Kd(self):
+ return self.Kd
+ @Kd.setter
+ def Kd(self, value):
+ self.Kd = value
+ @property
+ def Integrator(self):
+ return self.Integrator
+ @Integrator.setter
+ def Integrator(self, value):
+ self.Integrator = value
+ @property
+ def Derivator(self):
+ return self.Derivator
+ @Derivator.setter
+ def Derivator(self, value):
+ self.Derivator = value
+
+class PID_Arduino:
+ def __init__(self, Kp, Ki, Kd):
+ self.target = 0.0
+ self.last_input = None
+ self.last_error = 0.0
+ self.iterm = 0.0
+ self.sampletime = 100.0
+ self.out_max = 5000.0
+ self.out_min = 0.0
+ self.SetTunings(Kp, Ki, Kd)
+ @property
+ def point(self):
+ return self.target
+ @point.setter
+ def point(self, value):
+ self.target = float(value)
+ def SetTunings(self, Kp, Ki, Kd):
+ sampletime_secs = self.sampletime / 1000.0
+ self.Kp = float(Kp)
+ self.Ki = float(Ki) * sampletime_secs
+ self.Kd = float(Kd) / sampletime_secs
+ def SetSampleTime(self, ms):
+ ratio = float(ms) / self.sampletime
+ self.Ki *= ratio
+ self.Kd /= ratio
+ self.sampletime = float(ms)
+
+ def update(self, val):
+ val = float(val)
+ if self.last_input is None:
+ self.last_input = val
+ error = self.target - val
+ self.iterm += (self.Ki * error)
+ if self.iterm > self.out_max:
+ self.iterm = self.out_max
+ elif self.iterm < self.out_min:
+ self.iterm = self.out_min
+ #dv = val - self.last_input
+ de = error - self.last_error
+ PID = (self.Kp * error) + self.iterm - (self.Kd * de)
+ if PID > self.out_max:
+ PID = self.out_max
+ elif PID < self.out_min:
+ PID = self.out_min
+ self.last_input = val
+ self.last_error = error
+ return PID
+
+ def update2(self, val):
+ err = val - self.target
+ de = err - self.last_error;
+ self.iterm += self.Ki * self.iterm
+ PID = (self.Kp * err) + self.iterm + (self.Kd * de)
+ self.last_error = err
+ self.iterm += self.iterm
+ return PID
+
+import numpy as np
+import pylab as plt
+
+def main2(argv = None):
+ if argv is None:
+ argv = sys.argv
+ time,target,temp,output = np.loadtxt(argv[1],usecols=(0,1,2,3),unpack=True)
+ pid = PID3(0.3, 0.0, 5.0)
+ pid.SetPoint(target[0])
+ pideval = np.vectorize(pid.update)
+ pidres = pideval(time, temp)
+ #pid = PID_Arduino(0.8, 0.0, 0.0)
+ #pid.point = target[0]
+ #pideval = np.vectorize(pid.update2)
+ #pidres = pideval(temp)
+ print temp
+ print pidres
+ time /= 1000
+ time_plot, = plt.plot(time, temp)
+ plt.setp(time_plot, label='temperature')
+ #plt.plot(time, target)
+ #plt.plot(time, output)
+ pidres_plot, = plt.plot(time, pidres)
+ plt.setp(pidres_plot, label='PID output')
+ plt.ylabel("Temperature (\u00b0 C)")
+ plt.xlabel("Time (s)")
+ plt.grid(True)
+ plt.show()
+
+
+
+
+
+import Gnuplot, Gnuplot.funcutils
+
+#def plot_pid():
+
+def main3(argv = None):
+ if argv is None:
+ argv = sys.argv
+
+ with open(argv[1], 'r') as f:
+ pid = PID3(0.5, 0.0, 0.0)
+ for line in f:
+ if not line.startswith('#'):
+ T,Set,In,Out,Power = line.strip().split()
+ if not init:
+ pid.SetPoint(float(Set))
+ init = True
+ o = pid.update(int(T), float(In))
+ print T, In, Out, o
+ elif line.startswith('# PID'):
+ print line
+
+ gp = Gnuplot.Gnuplot(persist=1)
+ gp.clear()
+ gp.title('PID simulation')
+ gp.xlabel('Time (ms)')
+ #qplot_pid(1, 0, 0)
+ gp.plot(Gnuplot.File('z.log', using=(1,2), with_='lines', title="actual"),
+ Gnuplot.File('z.log', using=(1,4), with_='lines', title="predicted"))
+
+def main(argv = None):
+ if argv is None:
+ argv = sys.argv
+ if len(argv) < 2:
+ print("usage: simulate filename")
+ return 1
+
+ lines = []
+ init = False
+ with open(argv[1], 'r') as f:
+ #pid = PID(2.0,5.0,1.0)
+ #pid = PID_Arduino(2.0,5.0,1.0)
+ pid = PID3(0.5, 0.0, 0.0)
+ for line in f:
+ if not line.startswith('#'):
+ T,Set,In,Out,Power = line.strip().split()
+ if not init:
+ pid.SetPoint(float(Set))
+ init = True
+ o = pid.update(int(T), float(In))
+ print T, In, Out, o
+ elif line.startswith('# PID'):
+ print line
+
+ return 0
+
+
+if __name__=='__main__':
+ sys.exit(main2())
--- /dev/null
+#!/usr/bin/python
+
+import os,sys
+import numpy as np
+import pylab as plt
+
+class PID3:
+ """From http://www.chrismarion.net/index.php?option=com_content&view=article&id=166:adventures-in-pid-control&catid=44:robotics&Itemid=240"""
+ def __init__(self, Kp, Ki, Kd):
+ self.Kp = Kp
+ self.Ki = Ki
+ self.Kd = Kd
+ self.initialize()
+ def SetKp(self, Kp):
+ self.Kp = Kp
+ def SetKi(self, Ki):
+ self.Ki = Ki
+ def SetKd(self, Kd):
+ self.Kd = Kd
+ def SetPoint(self, point):
+ self.setpoint = point
+ def SetPrevErr(self, preverr):
+ self.prev_err = preverr
+ def initialize(self):
+ self.setpoint = 0
+ self.currtm = 0 #time.time()
+ self.prevtm = self.currtm
+ self.prev_err = 0
+ self.Cp = 0
+ self.Ci = 0
+ self.Cd = 0
+ def update(self, current_time, current_value):
+ """ Performs a PID computation and returns a control value based on the
+ elapased time (dt) and the error signal from a summing junction. """
+ self.currtm = current_time #get t
+ error = self.setpoint - current_value
+ dt = self.currtm - self.prevtm #get delta t
+ de = error - self.prev_err #get delta error
+ self.Cp = self.Kp * error #proportional term
+ self.Ci += error * dt #integral term
+ if self.Ci < 0:
+ self.Ci = 0
+ elif self.Ci > 5000:
+ self.Ci = 5000
+ self.Cd = 0
+ if dt > 0: #no div by zero
+ self.Cd = de/dt #derivative term
+ self.prevtm = self.currtm #save t for next pass
+ self.prev_err = error #save t-1 error
+ pid = self.Cp + (self.Ki * self.Ci) + (self.Kd * self.Cd)
+ if pid > 5000:
+ pid = 5000
+ elif pid < 0:
+ pid = 0
+ return pid
+
+def main(argv = None):
+ if argv is None:
+ argv = sys.argv
+ defaults = [None, 1.0, 0.0, 0.0]
+ filename,Kp,Ki,Kd = argv[1:] + defaults[len(argv)-1:]
+ if filename is None:
+ print("usage: simulate filename ?Kp? ?Kd? ?Ki?")
+ return 1
+
+ time,target,temp,output = np.loadtxt(argv[1],usecols=(0,1,2,3),unpack=True)
+ timex = time / 1000
+ time_plot, = plt.plot(timex, temp)
+ plt.setp(time_plot, label='temperature')
+
+ #for f in range(0,10,3):
+ #kd = (float(Kd) * f) / 1.0
+ kd = float(Kd)
+ pid = PID3(float(Kp), float(Ki), kd)
+ pid.SetPoint(target[0])
+ pideval = np.vectorize(pid.update)
+ pidres = pideval(timex, temp)
+ pidres_plot, = plt.plot(timex, pidres)
+ #c = ["#ff0000","#00ff00","#0000ff","#ffff00","#ff00ff","#00ffff"][f%6]
+ c="#00ffff"
+ plt.setp(pidres_plot, label='PID Kd %f' % (kd),color=c)
+
+ plt.title("PID Kp=%.3f Ki=%3f Kd=%.3f" % (pid.Kp, pid.Ki, pid.Kd))
+ plt.ylabel(u"Temperature (\u00b0 C)")
+ plt.xlabel("Time (s)")
+ plt.grid(True)
+ plt.show()
+
+if __name__=='__main__':
+ sys.exit(main())