A MAC unit with double carry-save scheme suitable for 6-input LUT based reconfigurable systems

“…Hardware multiplier based MAC unit with pipeline is fast, however, the proposed scheme is 25 per cent faster if pipeline is employed in the multi-operand adders. Moreover, the proposed scheme is faster than redundant MAC unit in [13] also requires much less logic elements. The results reveal that, proposed double carry-save redundant representation provides good performance metrics among the carry-propagate multipliers and hardware multiplier based implementations.…”

“…Next, multiply and accumulate operations are unified under the (6, 3) counter tree arrays. The reason for the usage of (6, 3) counters for the operations is that, (6,3) counter synthesis is very effective in 6-input based LUT structures, which is most popular for high performance reconfigurable systems [12,13].…”

“…If area requirement is not main concern, redundant reduction trees, such as (4, 2) compressors, binary-signed digit adder trees, counter trees can be used in FPGA multipliers. It is shown in [13] that (6,3) counters are very effective for the redundant addition operations and partial product reduction.…”

“…Here, each line represents generated partial product. The Booth encoding scheme is also explained in detail in [13].…”

MAC unit for reconfigurable systems using multi-operand adders with double carry-save encoding

“…Hardware multiplier based MAC unit with pipeline is fast, however, the proposed scheme is 25 per cent faster if pipeline is employed in the multi-operand adders. Moreover, the proposed scheme is faster than redundant MAC unit in [13] also requires much less logic elements. The results reveal that, proposed double carry-save redundant representation provides good performance metrics among the carry-propagate multipliers and hardware multiplier based implementations.…”

“…Next, multiply and accumulate operations are unified under the (6, 3) counter tree arrays. The reason for the usage of (6, 3) counters for the operations is that, (6,3) counter synthesis is very effective in 6-input based LUT structures, which is most popular for high performance reconfigurable systems [12,13].…”

“…If area requirement is not main concern, redundant reduction trees, such as (4, 2) compressors, binary-signed digit adder trees, counter trees can be used in FPGA multipliers. It is shown in [13] that (6,3) counters are very effective for the redundant addition operations and partial product reduction.…”

“…Here, each line represents generated partial product. The Booth encoding scheme is also explained in detail in [13].…”

MAC unit for reconfigurable systems using multi-operand adders with double carry-save encoding

“…Although optimization over carry-save adder schemes are implemented, the area requirement is still higher than carry propagate scheme. In [8] and [9] it is reported that (6,3) counter arrays give best performance result for the reduction of partial products and multi-operand addition input operand reduction, whenever 6-input LUT structures are implemented. In [9], register-to-register delays for various reduction schemes are analysed, which gives (6, 3) reduction gives best performance result.…”

Limited Carry-Propagate Multiply-Accumulate Unit Design for Reconfigurable Systems