Activity: Pulse Width Modulation

Objective

In this laboratory we examine pulse width modulation and its usage within a variety of applications.

Pulse Width Modulation (PWM) is a method for encoding an analog signal into a single digital bit. A PWM signal consists of two main components that define its behavior: a duty cycle and a frequency.

It is used in transmission of information by encoding a message into a pulsing signal, also for power control of electronic devices such as motors and as principal algorithm for photo-voltaic solar battery chargers.

The duty cycle describes the amount of time the signal is in a high (on) state as a percentage of the total time of it takes to complete one cycle.

The following diagram shows pulse trains at 0%, 25%, and 100% duty cycle.

The frequency determines how fast the PWM completes a cycle, and therefore how fast it switches between high and low states.

By varying a digital signal off and on at a fast-enough rate, and with a certain duty cycle, the output will appear to behave like a constant voltage analog signal when providing power to devices that respond much slower than the PWM frequency, such as audio speakers, electric motors, and solenoid actuators.

Materials

ADALM2000 Active Learning Module
Solder-less breadboard, and jumper wire kit
1 OP97 operational amplifier
1 1kΩ resistor 1 10kΩ potentiometer

Pulse Width Modulator - Principle of operation

Pulse Width Modulation (PWM) is a technique to generate low frequency output signals from high frequency pulses. Rapidly switching the output voltage of an inverter leg between the upper and lower DC rail voltages, the low frequency output can be thought of as the average of voltage over a switching period.

Besides that, there are also other several ways of generating pulse-width modulated signals, including analog techniques, sigma-delta modulation, and direct digital synthesis.

One of the simplest methods of generating a PWM signal is to compare two control signals, a carrier signal and a modulation signal. This is known as carrier-based PWM. The carrier signal is a high frequency (switching frequency) triangular waveform. The modulation signal can be any shape.

Using this approach, the output waveform can be a PWM representation of any desired waveform shape. With machines, sinusoidal and trapezoidal waveform shapes are among the most common.

Consider the circuit in Figure 1.

Figure 1. PWM Principle of operation

Following the description of the PWM principle, we use the negative input of the operational amplifier for carrier, while the positive input for the modulation signal. Thus, a higher modulation signal will result in an output that is at a high level for a greater fraction of the PWM period.

Hardware Setup

Build the following breadboard circuit for Pulse Width Modulation.

Figure 2. PWM Principle of operation - breadboard circuit

Procedure

Use the first waveform generator as the carrier signal providing a 4V amplitude, 2.5V offset, 1 kHz triangle wave excitation to the circuit. Use the second waveform generator as the modulation signal with 3V amplitude, 2.5V offset, 50Hz sine wave.

Supply the op amp with +5V from the power supply. Configure the scope so that the input signal is displayed on channel 1 and the output signal is displayed on channel 2 .

In the figure there are presented the two signal generator channels containing the two input signals (orange - carrier signal, purple - modulation signal).

Figure 3. Input Signals

A plot of the output signal on channel 2 of the scope is presented in Figure 4.

Figure 4. PWM output

If the instantaneous magnitude of the modulation signal is greater than the carrier signal at a point in time, the output will be high. If the modulation signal is lower than the carrier signal, the output will be low.

If the peak of the modulation is less than the peak of the carrier signal, the output will be a faithful PWM representation of the modulation signal. Edit

Pulse Width Control using a DC modulation Voltage

Background

For this particular application we will use a simple operational amplifier in a switching mode configuration (see Activity: Op Amp as Comparator for further details) to demonstrate pulse-width modulation of a DC voltage.

Consider the circuit in Figure 5.

Figure 5. Pulse Width Control using a DC modulation Voltage

The circuit works as a simple comparator where the negative input of the operational amplifier is connected to the carrier waveform, while the positive input acts as a threshold voltage which establishes when the transitions between high voltage output and low voltage output occur. The potentiometer acts as a voltage divider for the input reference voltage, adjusting the threshold voltage, and implicitly the duty cycle of the output signal.