Reconfigurable Multiplier Blocks (ReMB) offer significant area, delay and possibly power reduction in time-multiplexed implementation of multiple constant multiplications. This paper and its companion paper (entitled Part I- Fundamentals) together present a systematic synthesis method for Single Input Single Output (SISO) and Single Input Multiple Output (SIMO) ReMB designs. This paper illustrates the synthesis method through examples. The companion paper presents the necessary foundation and terminology needed for developing a systematic synthesis technique. The proposed method achieves reduced logic-depth and area over standard multipliers / multiplier blocks
International audienceOptimizing the number of additions in constant coefficient multiplication is c...
A multiplier is one of the key hardware blocks in most digital and high performance systems such as ...
In this study, three multiplier-blocks generated by different algorithms are analyzed for their powe...
Reconfigurable Multiplier Blocks (ReMB) offer significant area, delay and possibly power reduction i...
The newly proposed reconfigurable multiplier blocks offer significant savings in area over the trad...
Reconfigurable Multiplier Blocks (ReMB) offer significant complexity reductions in multiple constant...
The depth of logic in an integrated circuit, particularly a CMOS circuit, is highly correlated both ...
The multiplication and multiply-accumulate operations are expensive to implement in hardware for Dig...
The recent growth in microprocessor performance has been a direct result of designers exploiting dec...
International audienceThis paper addresses the problem of multiplication with large operand sizes (N...
During the last decade of integrated electronic design ever more functionality has been integrated o...
International audienceIn this paper, a new recursive multibit recoding multiplication algorithm is i...
Multipliers are used in most arithmetic computing systems such as 3D graphics, signal processing, a...
Multiplications occur frequently in digital signal processing systems, communication systems, and ot...
174 p.Multipliers, being the area and power hungry units, are deciding factors to the overall area, ...
International audienceOptimizing the number of additions in constant coefficient multiplication is c...
A multiplier is one of the key hardware blocks in most digital and high performance systems such as ...
In this study, three multiplier-blocks generated by different algorithms are analyzed for their powe...
Reconfigurable Multiplier Blocks (ReMB) offer significant area, delay and possibly power reduction i...
The newly proposed reconfigurable multiplier blocks offer significant savings in area over the trad...
Reconfigurable Multiplier Blocks (ReMB) offer significant complexity reductions in multiple constant...
The depth of logic in an integrated circuit, particularly a CMOS circuit, is highly correlated both ...
The multiplication and multiply-accumulate operations are expensive to implement in hardware for Dig...
The recent growth in microprocessor performance has been a direct result of designers exploiting dec...
International audienceThis paper addresses the problem of multiplication with large operand sizes (N...
During the last decade of integrated electronic design ever more functionality has been integrated o...
International audienceIn this paper, a new recursive multibit recoding multiplication algorithm is i...
Multipliers are used in most arithmetic computing systems such as 3D graphics, signal processing, a...
Multiplications occur frequently in digital signal processing systems, communication systems, and ot...
174 p.Multipliers, being the area and power hungry units, are deciding factors to the overall area, ...
International audienceOptimizing the number of additions in constant coefficient multiplication is c...
A multiplier is one of the key hardware blocks in most digital and high performance systems such as ...
In this study, three multiplier-blocks generated by different algorithms are analyzed for their powe...