Vijay KumarKnowledge Contributor
Describe the operation of a pulse generator in digital systems.
Describe the operation of a pulse generator in digital systems.
Sign Up to our social questions and Answers Engine to ask questions, answer people’s questions, and connect with other people.
Login to our social questions & Answers Engine to ask questions answer people’s questions & connect with other people.
Lost your password? Please enter your email address. You will receive a link and will create a new password via email.
Please briefly explain why you feel this question should be reported.
Please briefly explain why you feel this answer should be reported.
Please briefly explain why you feel this user should be reported.
Questions | Answers | Discussions | Knowledge sharing | Communities & more.
Clock Source: The pulse generator may have an internal clock source, such as a crystal oscillator or a reference clock signal, or it may receive an external clock signal as input. The clock signal serves as the timing reference for generating pulses.
Timing Control: The pulse generator includes circuitry to control the timing parameters of the generated pulses, including frequency, duty cycle, pulse width, and rise/fall times. These parameters are typically set by the user through control inputs or configuration registers.
Waveform Generation: Depending on the application and requirements, the pulse generator can produce different types of waveforms, including square waves, rectangular pulses, or pulses with specific shapes (e.g., trapezoidal, triangular). The waveform generation circuitry generates the desired waveform based on the configured timing parameters.
Triggering Mechanism: In many pulse generators, a triggering mechanism is provided to initiate the generation of pulses. The trigger can be external, where an external signal or event activates the pulse generator, or internal, where the pulse generator generates pulses periodically based on its internal clock source.
Output Stage: The generated pulses are output from the pulse generator through one or more output channels. The output stage may include amplification, buffering, or signal conditioning circuitry to ensure that the output pulses meet the specified voltage levels, impedance requirements, and drive capabilities.
Control and Configuration: Pulse generators often include control interfaces or configuration options to adjust the timing parameters and operating modes of the generator. This allows users to customize the pulse characteristics according to the specific requirements of their application.
Applications: Pulse generators find applications in various fields such as digital communications, instrumentation, testing and measurement, signal processing, and control systems. They are used for tasks such as clock synchronization, pulse-width modulation (PWM), pulse-position modulation (PPM), triggering of electronic devices, and generating test signals for circuit testing and characterization.
Accuracy and Precision: Pulse generators are designed to provide precise and accurate pulse timing, ensuring that the generated pulses meet the specified timing requirements with minimal jitter, drift, or distortion. High-quality pulse generators offer adjustable parameters and stable operation over a wide range of operating conditions.