Partial Bus-Invert Bus Encoding Schemes for Low-Power DSP Systems Considering Inter-wire Capacitance

“…It is able to reduce the transition activity, but it is not able to fully exploit the larger opportunities offered by the signal with t MSB = 0.1. A combination of Bus-Invert with non-redundant memoryless coding [4] is advisable.…”

“…Further on, a wide range of approaches have been developed to improve the performance of the basic Bus-Invert scheme. Several approaches referred as Partial Bus-Invert advocate for coding a part of the bus only (see [7], [4] and reference there), while other techniques combine Bus-Invert with other schemata as non-redundant memoryless coding [4] or even more complex approaches as Berger codes [1]. Without a suitable mathematical analysis of the different coding techniques (and their alternatives) it is not possible to exploit them early in the design flow.…”

“…Low-power coding for on-chip and off-chip interconnects is emerging [1], [2], [3], [4] as an important technique for overcoming the increasing power budgets required for the communication architecture of modern chips. As technology shrinks, the impact of the interconnects in the overall system power and system performance is increasing.…”

“…[3]. Initially, the technique was designed to address the switching activity only, however, several extensions as Odd/Even Bus-Invert have been proposed for reducing the coupling activity as well (see [6], [4] and references there). Further on, a wide range of approaches have been developed to improve the performance of the basic Bus-Invert scheme.…”

Analysis of Bus-Invert coding in the presence of correlations

“…It is able to reduce the transition activity, but it is not able to fully exploit the larger opportunities offered by the signal with t MSB = 0.1. A combination of Bus-Invert with non-redundant memoryless coding [4] is advisable.…”

“…Further on, a wide range of approaches have been developed to improve the performance of the basic Bus-Invert scheme. Several approaches referred as Partial Bus-Invert advocate for coding a part of the bus only (see [7], [4] and reference there), while other techniques combine Bus-Invert with other schemata as non-redundant memoryless coding [4] or even more complex approaches as Berger codes [1]. Without a suitable mathematical analysis of the different coding techniques (and their alternatives) it is not possible to exploit them early in the design flow.…”

“…Low-power coding for on-chip and off-chip interconnects is emerging [1], [2], [3], [4] as an important technique for overcoming the increasing power budgets required for the communication architecture of modern chips. As technology shrinks, the impact of the interconnects in the overall system power and system performance is increasing.…”

“…[3]. Initially, the technique was designed to address the switching activity only, however, several extensions as Odd/Even Bus-Invert have been proposed for reducing the coupling activity as well (see [6], [4] and references there). Further on, a wide range of approaches have been developed to improve the performance of the basic Bus-Invert scheme.…”

Analysis of Bus-Invert coding in the presence of correlations

“…These techniques increase the bit-width of the codewords over the plain data words by one inversion line. Also, application-specific low-power codes, for example for signal processing [9], [13] or address buses [8], [10], [11], were designed. Compared to inversion codes, they are overhead-free (i.e., codeword bit-width equal to dataword bit-width) and/or yield much higher power savings while exhibiting a lower implementation complexity.…”

Exploiting Neural-Network Statistics for Low-Power DNN Inference

On the Necessity of Combining Coding with Spacing and Shielding for Improving Performance and Power in Very Deep Sub-micron Interconnects