Multiplier-Cum-Divider Circuits: Principles, Design, and Applications

This paper explores the design and implementation of multiplier-cum-divider circuits using various types of generators, including saw tooth and triangular wave generators. It also discusses the development of functional circuits with simple integrators and comparators.

\n Format: Hardback
\n Length: 216 pages
\n Publication date: 13 July 2021
\n Publisher: Taylor & Francis Ltd
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Here is the rephrased text:
Multiplier-cum-divider circuits are essential components in electronic systems, enabling the multiplication and division of signals. In this comprehensive article, we delve into the various types of multiplier-cum-divider circuits, their architecture, and the development of new methodologies to derive these circuits using saw tooth wave generators and triangular wave generators. We also explore the creation of functional circuits with simple integrators and comparators, highlighting their applications in signal processing and control systems.

Multiplier-cum-divider circuits are versatile devices that find applications in a wide range of electronic systems. They are used for performing arithmetic operations such as multiplication, division, and square root extraction. These circuits can be implemented using various techniques, including digital and analog methods.

One of the most common types of multiplier-cum-divider circuits is the digital multiplier-cum-divider (DMD). It is a digital circuit that performs multiplication and division operations on binary numbers. The DMD consists of a number of flip-flops, which are used to store the intermediate results of the multiplication and division operations. The circuit also includes a control logic that determines the order of the operations and the timing of the flip-flops.

Another type of multiplier-cum-divider circuit is the analog multiplier-cum-divider (AMD). It is an analog circuit that performs multiplication and division operations on analog signals. The AMD consists of a number of operational amplifiers, which are used to amplify the input signals and perform the multiplication and division operations. The circuit also includes a control logic that determines the gain of the amplifiers and the timing of the operations.

Multiplier-cum-divider circuits can also be derived using saw tooth wave generators and triangular wave generators. Saw tooth wave generators are used to generate square wave signals, which can be used to generate the clock signal for the multiplier-cum-divider circuit. Triangular wave generators are used to generate triangular wave signals, which can be used to generate the clock signal for the multiplier-cum-divider circuit.

The architecture of multiplier-cum-divider circuits is typically divided into three main parts: the multiplier, the divider, and the control logic. The multiplier is responsible for performing the multiplication and division operations. The divider is responsible for dividing the input signal into two parts. The control logic is responsible for controlling the timing and order of the operations.

In addition to multiplier-cum-divider circuits, functional circuits with simple integrators and comparators can also be developed. These circuits are used for performing logical operations such as AND, OR, and XOR. The integrator is used to integrate the input signal, while the comparator is used to compare the input signal with a reference signal.

Functional circuits with simple integrators and comparators have a wide range of applications in signal processing and control systems. They can be used for filtering, shaping, and detecting signals. They can also be used for implementing digital logic circuits, such as flip-flops and counters.

In conclusion, multiplier-cum-divider circuits are essential components in electronic systems, enabling the multiplication and division of signals. In this comprehensive article, we have discussed the various types of multiplier-cum-divider circuits, their architecture, and the development of new methodologies to derive these circuits using saw tooth wave generators and triangular wave generators. We have also explored the creation of functional circuits with simple integrators and comparators, highlighting their applications in signal processing and control systems.

\n Weight: 498g\n
Dimension: 160 x 242 x 22 (mm)\n
ISBN-13: 9780367754464\n \n