We describe a hardware-oriented design of a complex division algorithm proposed in.1 This algorithm is similar to a radix-r digit-recurrence division algorithm with real operands and prescaling. Prescaling of complex operands allows efficient selection of complex quotient digits in higher radix. The use of the digit-recurrence method allows hardware implementation similar to that of conventional dividers. Moreover, this method makes correct rounding of complex quotient possible. On the other hand, the proposed scheme requires the use of prescaling tables which are more demanding than tables in similar dividers with real operands. In this paper we present main design ideas, implementation details, and give a rough estimate of the expected la...
International audienceThis paper shows the details of an implementation of variable radix floating-p...
Abstract — A hardware algorithm for integer division is pro-posed. It is based on the digit-recurren...
Abstract—We present a radix-10 digit-recurrence algorithm for division using limited-precision multi...
We adapt the radix-r digit-recurrence division algorithm to complex division. By prescaling the oper...
(eng) We adapt the radix-$r$ digit-recurrence division algorithm to complex division. By prescaling ...
We describe a hardware-oriented design of a complex division algorithm proposed in
We adapt the radix-r digit-recurrence division algorithm to complex division. By prescaling the oper...
(eng) We propose a radix-$r$ digit-recurrence algorithm for complex square-root. The operand is pres...
We adapt the radix-r digit-recurrence division algorithm to complex division. By prescaling the oper...
Abstract. We propose a radix-r digit-recurrence algorithm for complex square-root. The operand is pr...
The purpose of the thesis was to investigate and evaluate existing algorithms for division of comple...
We propose a digit-recurrence algorithm for division in real and complex number domains using a vari...
We propose a radix-r digit-recurrence algorithm for complex square-root. The operand is prescaled to...
International audienceWe present a design and implementation of a radix-4 complex division unit with...
In this paper, we propose a class of division algorithms with the aim of reducing the delay of the s...
International audienceThis paper shows the details of an implementation of variable radix floating-p...
Abstract — A hardware algorithm for integer division is pro-posed. It is based on the digit-recurren...
Abstract—We present a radix-10 digit-recurrence algorithm for division using limited-precision multi...
We adapt the radix-r digit-recurrence division algorithm to complex division. By prescaling the oper...
(eng) We adapt the radix-$r$ digit-recurrence division algorithm to complex division. By prescaling ...
We describe a hardware-oriented design of a complex division algorithm proposed in
We adapt the radix-r digit-recurrence division algorithm to complex division. By prescaling the oper...
(eng) We propose a radix-$r$ digit-recurrence algorithm for complex square-root. The operand is pres...
We adapt the radix-r digit-recurrence division algorithm to complex division. By prescaling the oper...
Abstract. We propose a radix-r digit-recurrence algorithm for complex square-root. The operand is pr...
The purpose of the thesis was to investigate and evaluate existing algorithms for division of comple...
We propose a digit-recurrence algorithm for division in real and complex number domains using a vari...
We propose a radix-r digit-recurrence algorithm for complex square-root. The operand is prescaled to...
International audienceWe present a design and implementation of a radix-4 complex division unit with...
In this paper, we propose a class of division algorithms with the aim of reducing the delay of the s...
International audienceThis paper shows the details of an implementation of variable radix floating-p...
Abstract — A hardware algorithm for integer division is pro-posed. It is based on the digit-recurren...
Abstract—We present a radix-10 digit-recurrence algorithm for division using limited-precision multi...