DIGITAL_FOURIER
A sine-wave generator produces a Walsh-function approximation of the sine function. The frequency of the sine wave is determined by a square-wave input to pin 14 of a 7493 integrated circuit. Filter components of the operational amplifier assist in smoothing the staircase waveform generated by summing Walsh-function components, which are weighted by resistors. The circuit functions as a converter that includes a digital expander to expand the input square wave.
The sine-wave generator circuit utilizes a 7493 binary counter to generate a square wave input that defines the frequency of the output sine wave. The square wave is fed into pin 14 of the 7493, which is configured to produce a series of binary outputs. These outputs are then processed to create Walsh functions, which are mathematical functions that serve as orthogonal basis functions. The Walsh functions are combined in such a way that they approximate a sine wave.
To achieve the smoothing of the staircase waveform, an operational amplifier (op-amp) is employed. The op-amp is configured in a low-pass filter arrangement, which effectively reduces the high-frequency components of the staircase waveform. The filter components, including resistors and capacitors, are selected to ensure that the desired frequency response is achieved, allowing for a smooth transition between the discrete steps of the staircase waveform.
The weighting of the Walsh-function components is accomplished through a network of resistors that determine the contribution of each component to the final output. This weighting process is crucial for accurately shaping the output waveform to closely resemble a true sine wave.
In addition to the sine-wave generation, the circuit also includes a digital expander. This component expands the input square wave, allowing for a broader range of output frequencies and improving the versatility of the circuit. The digital expander operates by taking the input signal and generating additional output signals that replicate the characteristics of the original square wave, thereby enhancing the overall performance of the sine-wave generator.
Overall, this circuit design provides an effective method for generating sine waves using digital components and analog filtering techniques, making it suitable for various applications in signal processing and waveform generation.Sine-wave generator produces Walsh-function approximation of sine function. Frequency of sine wave is set by square-wave input to pin 14 of 7493. Filter com ponents of opamp help smooth staircase wave form generated by summing Walsh-function components as weighted by resistors. Circuit is converter consisting of digital expander that expands input square wav.. 🔗 External reference
The sine-wave generator circuit utilizes a 7493 binary counter to generate a square wave input that defines the frequency of the output sine wave. The square wave is fed into pin 14 of the 7493, which is configured to produce a series of binary outputs. These outputs are then processed to create Walsh functions, which are mathematical functions that serve as orthogonal basis functions. The Walsh functions are combined in such a way that they approximate a sine wave.
To achieve the smoothing of the staircase waveform, an operational amplifier (op-amp) is employed. The op-amp is configured in a low-pass filter arrangement, which effectively reduces the high-frequency components of the staircase waveform. The filter components, including resistors and capacitors, are selected to ensure that the desired frequency response is achieved, allowing for a smooth transition between the discrete steps of the staircase waveform.
The weighting of the Walsh-function components is accomplished through a network of resistors that determine the contribution of each component to the final output. This weighting process is crucial for accurately shaping the output waveform to closely resemble a true sine wave.
In addition to the sine-wave generation, the circuit also includes a digital expander. This component expands the input square wave, allowing for a broader range of output frequencies and improving the versatility of the circuit. The digital expander operates by taking the input signal and generating additional output signals that replicate the characteristics of the original square wave, thereby enhancing the overall performance of the sine-wave generator.
Overall, this circuit design provides an effective method for generating sine waves using digital components and analog filtering techniques, making it suitable for various applications in signal processing and waveform generation.Sine-wave generator produces Walsh-function approximation of sine function. Frequency of sine wave is set by square-wave input to pin 14 of 7493. Filter com ponents of opamp help smooth staircase wave form generated by summing Walsh-function components as weighted by resistors. Circuit is converter consisting of digital expander that expands input square wav.. 🔗 External reference