The speed of high-radix digit-recurrence dividers and square-root units is mainly determined by the complexity of the result-digit selection. We present a scheme in which a simpler function speculates the result digit, and, when this speculation is incorrect, a rollback or a partial advance is performed. This results in operations with a shorter cycle time and a variable number of cycles. The scheme can be used in separate division and square-root units, or in a combined one. Several designs were realized and compared in terms of execution time and area. The fastest unit considered is a radix-512 divider with a partial advance of six bits.Peer ReviewedPostprint (published version
We propose a digit-recurrence algorithm for division in real and complex number domains using a vari...
An extension of the very-high radix division with prescaling and selection by rounding is presented....
High-radix division, developing several quotient bits per clock, is usually limited by the difficult...
The speed of high-radix digit-recurrence dividers and square-root units is mainly determined by the ...
The speed of SRT-type dividers is mainly determined by the complexity of the quotient-digit selectio...
The speed of a divider based on a digit-recurrence algorithm depends mainly on the latency of the qu...
In this paper, we propose a class of division algorithms with the aim of reducing the delay of the s...
The speed of high-radix digit-recurrence dividers is mainly determined by the hardware complexity of...
ISBN: 0818669055The digit-recurrence division relies on a sequence of addition/subtraction and shift...
: The digit-recurrence division relies on a sequence of addition/subtraction and shift operations i...
An algorithm for square root with prescaling and selection by rounding is developed and combined wit...
Abstract—Division and square root, based on the digit-recurrence algorithm, can be implemented in a ...
We describe a hardware-oriented design of a complex division algorithm proposed in.1 This algorithm ...
This paper presents the design of a radix-4, 32-bit integer divider which uses a recursive, non-rest...
This paper presents a derivation of four radix-2 division algorithms by digit recurrence. Each divis...
We propose a digit-recurrence algorithm for division in real and complex number domains using a vari...
An extension of the very-high radix division with prescaling and selection by rounding is presented....
High-radix division, developing several quotient bits per clock, is usually limited by the difficult...
The speed of high-radix digit-recurrence dividers and square-root units is mainly determined by the ...
The speed of SRT-type dividers is mainly determined by the complexity of the quotient-digit selectio...
The speed of a divider based on a digit-recurrence algorithm depends mainly on the latency of the qu...
In this paper, we propose a class of division algorithms with the aim of reducing the delay of the s...
The speed of high-radix digit-recurrence dividers is mainly determined by the hardware complexity of...
ISBN: 0818669055The digit-recurrence division relies on a sequence of addition/subtraction and shift...
: The digit-recurrence division relies on a sequence of addition/subtraction and shift operations i...
An algorithm for square root with prescaling and selection by rounding is developed and combined wit...
Abstract—Division and square root, based on the digit-recurrence algorithm, can be implemented in a ...
We describe a hardware-oriented design of a complex division algorithm proposed in.1 This algorithm ...
This paper presents the design of a radix-4, 32-bit integer divider which uses a recursive, non-rest...
This paper presents a derivation of four radix-2 division algorithms by digit recurrence. Each divis...
We propose a digit-recurrence algorithm for division in real and complex number domains using a vari...
An extension of the very-high radix division with prescaling and selection by rounding is presented....
High-radix division, developing several quotient bits per clock, is usually limited by the difficult...