[[abstract]]Division operation is very important in computer systems. Conventionally synchronous techniques are applied to implement the divider. In this paper we propose a new asynchronous architecture for the divider. In this asynchronous scheme, the architecture is simple and is very easy to implement in VLSI. With this asynchronous architecture, we use TSMC's 0.6 um SPDM process to design a 32-b/32-b radix-2 non-restoring divider. The HSPICE simulation shows that this divider can finish a 32-b/32-b division operation in 3.7 ns to 160.2 ns[[conferencetype]]國際[[conferencedate]]19980531~19980603[[conferencelocation]]Monterey, CA, US
We describe a hardware-oriented design of a complex division algorithm proposed in.1 This algorithm ...
The speed of SRT-type dividers is mainly determined by the complexity of the quotient-digit selectio...
The ever increasing demand in VLSI architecture to handle complex systems has resulted for designing...
[[abstract]]Division operation is very important in the computer system. Nowadays people use a hardw...
The speed of high-radix digit-recurrence dividers is mainly determined by the hardware complexity of...
Abstract — This paper deals with design of non-restoring divider using Shannon based adder with pass...
Synchronous systems represent the majority of digital circuits built, essentially because they are e...
This paper presents the design of a radix-4, 32-bit integer divider which uses a recursive, non-rest...
[[abstract]]A new floating-point division architecture that complies with the IEEE 754-1985 standard...
The division operation is essential in many digital signal processing algorithms. For a hardware imp...
[[abstract]]A novel floating-point division architecture with IEEE 754-1985 standard is proposed in ...
Abstract: The hardware organization of the high-radix SRT division is categorized into two classes w...
ISBN: 0818669055The digit-recurrence division relies on a sequence of addition/subtraction and shift...
ISBN: 0818669055The development of a new general radix-b division algorithm, based on the Svoboda-Tu...
A complex system, such as a computer system, is seen to be composed with several levels of abstracti...
We describe a hardware-oriented design of a complex division algorithm proposed in.1 This algorithm ...
The speed of SRT-type dividers is mainly determined by the complexity of the quotient-digit selectio...
The ever increasing demand in VLSI architecture to handle complex systems has resulted for designing...
[[abstract]]Division operation is very important in the computer system. Nowadays people use a hardw...
The speed of high-radix digit-recurrence dividers is mainly determined by the hardware complexity of...
Abstract — This paper deals with design of non-restoring divider using Shannon based adder with pass...
Synchronous systems represent the majority of digital circuits built, essentially because they are e...
This paper presents the design of a radix-4, 32-bit integer divider which uses a recursive, non-rest...
[[abstract]]A new floating-point division architecture that complies with the IEEE 754-1985 standard...
The division operation is essential in many digital signal processing algorithms. For a hardware imp...
[[abstract]]A novel floating-point division architecture with IEEE 754-1985 standard is proposed in ...
Abstract: The hardware organization of the high-radix SRT division is categorized into two classes w...
ISBN: 0818669055The digit-recurrence division relies on a sequence of addition/subtraction and shift...
ISBN: 0818669055The development of a new general radix-b division algorithm, based on the Svoboda-Tu...
A complex system, such as a computer system, is seen to be composed with several levels of abstracti...
We describe a hardware-oriented design of a complex division algorithm proposed in.1 This algorithm ...
The speed of SRT-type dividers is mainly determined by the complexity of the quotient-digit selectio...
The ever increasing demand in VLSI architecture to handle complex systems has resulted for designing...