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Raspberry pi Encoder with python not plotting graph showing RPM -OPEN

I have tried many times but unable to get what could be the issue in this I have attached the raspberry pi 4 with hall effect encoder using only X1 decoding for encoder, PPR is 160, and also have include dynamic model but unable to execute it properly to run on open loop. I m also filttering the singnal by usiign low pass filter, its working fine with PID but unable to get results on simple Open loop system.

   import RPi.GPIO as GPIO
    import numpy as np
    import time
    import matplotlib.pyplot as plt 
    from time import sleep
    import random
    import sensormotion as sm
    from motor_model import motor
    from scipy.integrate import odeint
    #Defining GPIO PINS
    GPIO.setmode(GPIO.BCM)
    GPIO.setup(17, GPIO.IN, pull_up_down=GPIO.PUD_UP) #Sensor Input Aout
    GPIO.setup(18, GPIO.OUT) #PWM PIN
    GPIO.setup(27, GPIO.OUT) #Left Direction
    GPIO.setup(22, GPIO.OUT) #Right Direction
    #Initial Setup Setup
    simulationTime = 10 #Total Simulation time for the Motor
    samplingTime = 0.01 #Sampling time for each tick count
    setPoint = 500  #Desire RPM
    count = 0   #counting the ticks of the motor
    refperiod = 5 #PWM period  time taken by PWM to complete one cycle.
    pwmResolution = 4096 # 4096 steps Because of raspberry pi 4 has 12bit resolution has factor 0.00024
    simulationTime = int(1000 / 24 * simulationTime) #converting Raspberry pi  from resolution factor 0.00024
    refperiod = int(1000 / 24 * refperiod)
    encoderCount = 55 #assuming Pulse Per Revolution here
    scale = 1 / samplingTime  #frequency of the tick count
    pwmOut = GPIO.PWM(18, 1 / samplingTime)  # GPIO.PWM ([pin],frequency]) here 100Hz when simulation time is 0.01
    try:
       while True:
    ##########Couting the encoder up pulses
            def counterup(channel):
                global count
                if GPIO.input(channel) == 1:
                    count += 1
                else:
                    count += 0
                    print(count)
            #Enocder ticks count to RPM conversion
            def speedConvert():           
                speedDC = count * 60 * scale / encoderCount
                print(speedDC)
                return speedDC        
    ####  MotorDirection Setting
            def motorDirection(direction):
                # Counter Clockwise Direction
                if direction == 'ccw': 
                    GPIO.output(27, 1)
                    GPIO.output(22, 0)
                # Clockwise Direction
                elif direction == 'cw': 
                    GPIO.output(27, 0)
                    GPIO.output(22, 1)
                else: # Stop the Motor
                    GPIO.output(27, 0)
                    GPIO.output(22, 0)
            motorDirection ('cw')        
            #intializing arrays for saving values
            y = np.array([])    
            t = np.linspace(0,20)
            for x in range (0,20):
                count = 0
                GPIO.add_event_detect(17, GPIO.RISING, callback = counterup)
                sensorRead = speedConvert()
                pwmOut.start(50)
                y = np.append(y,sensorRead)
                sleep(samplingTime) #Updating Error after each sampling time that is 0.01 or 1 ms
                  #Intialzing count here for the update 
            #If all the above logic fails motor will not run
             else :
                 pwmOut.start(0)
    ####################Singal Filtering#############################
    # #-------------------------LOW PASS FILTER
    #    #     t = np.multiply(t, 24 / 1000)
    #         sampling_rate = 1000
    #         #Building  a butterworth filter with specified parameters.
    #         #                            Frequency, sampling rate, filter type, filter order
    #         b, a = sm.signal.build_filter(5.7, sampling_rate, 'low', filter_order=1)
    #         y_f = sm.signal.filter_signal(b, a, y)  # Filtering Encoder Data
    #      
    ##################Dc Motor Model Plot# #################################################
    # Parameter for Dc motor
    #         J = 0.01  # [kg.m^2]   Moment of inertia of motor
    #         b = 0.1  # [N.m.s]    Damping ratio of mechanical system
    #         K = 0.01  # constant Ke= Kt = K
    #         R = 1  # [ohm]      Electrical resistance
    #         L = 0.5  # [H]   Electrical inductance
    #                
    #         y0 = [ 0,0,0]
    #         ym= odeint(motor, y0, t )     
    ######################Comparative results of Low pass and Orignal Signal#################     
            print(y)       
            plt.figure(figsize=(6, 5))
    #         plt.plot(t, ym[:, 2], color='b', linewidth = 2,label = 'Simulated Result')
            plt.plot(t, y, 'k' , linewidth = 0.3 ,label='Encoder Output')
    #         plt.plot(t, y_f, color='g', linewidth = 2,label = 'Low Pass Filter')
            plt.title("Comparative Results of Reference Signal, Simulated Output and Encoder Output with Low Pass Filter")
            plt.xlabel('Time [s]')
            plt.ylabel('Speed (RPM [rad/s]')
            plt.legend(loc='upper right')
            plt.grid()
            plt.show()
            #after Completting the loop
            motorDirection('stop')
    except KeyboardInterrupt:
        print("program interrupted")
    finally:
        GPIO.cleanup()