In some examples, a device includes an integrated circuit comprising a computational unit configured to process at least two input bit streams that each include a sequential set of data bits or two or more sets of data bits in parallel that is deterministically encoded to represent numerical values based on a probability that any data bit in the bit stream is high. In some examples, the computational unit includes a convolver configured to generate pair-wise bit combinations of the data bits of the input bit streams. In some examples, e computational unit further includes a stochastic computational unit configured to perform a computational operation on the pair-wise bit combinations and produce an output bit stream having a set of data bits indicating a result of the computational operation based on a probability that any data bit in the set of data bits of the output bit stream is high.

Disclosed herein are three context-aware architectures to accelerate the three state-of-the-art deterministic methods of SC. The proposed designs employ a control unit to extract the minimum bit-width required to precisely represent each input data. The lengths of bit-streams are reduced to the minimum lengths required to precisely represent each input data. The noise-tolerance property of the designs is preserved as each bit-flip can only introduce a least significant bit error. The proposed designs achieve a considerable improvement in the processing time at a reasonable hardware cost overhead. The proposed designs make the deterministic bit-stream processing more appealing for applications that expect highly accurate computation and also for error-tolerant applications.

Disclosed herein are three context-aware architectures to accelerate the three state-of-the-art deterministic methods of SC. The proposed designs employ a control unit to extract the minimum bit-width required to precisely represent each input data. The lengths of bit-streams are reduced to the minimum lengths required to precisely represent each input data. The noise-tolerance property of the designs is preserved as each bit-flip can only introduce a least significant bit error. The proposed designs achieve a considerable improvement in the processing time at a reasonable hardware cost overhead. The proposed designs make the deterministic bit-stream processing more appealing for applications that expect highly accurate computation and also for error-tolerant applications.

The present disclosure relates to circuitry for performing a multiply-accumulate (MAC) operation. The circuitry comprises a first multiplexer having a plurality of inputs for receiving a plurality of unary-coded input signals representing operands of the MAC operation and an output for outputting a multiplexer output signal representing a result of the MAC operation and a first vector quantizer configured to receive a plurality of weighting signals, each representing a proportion of a computation time period for which a respective one of the unary-coded input signals should be selected by the multiplexer and to output a first selector signal to the multiplexer to cause the multiplexer to select each of the input signals in accordance with the plurality of weighting signals.

The present disclosure relates to circuitry for performing a multiply-accumulate (MAC) operation. The circuitry comprises a first multiplexer having a plurality of inputs for receiving a plurality of unary-coded input signals representing operands of the MAC operation and an output for outputting a multiplexer output signal representing a result of the MAC operation and a first vector quantizer configured to receive a plurality of weighting signals, each representing a proportion of a computation time period for which a respective one of the unary-coded input signals should be selected by the multiplexer and to output a first selector signal to the multiplexer to cause the multiplexer to select each of the input signals in accordance with the plurality of weighting signals.

The present disclosure relates to circuitry for performing a multiply-accumulate (MAC) operation. The circuitry comprises a first multiplexer having a plurality of inputs for receiving a plurality of unary-coded input signals representing operands of the MAC operation and an output for outputting a multiplexer output signal representing a result of the MAC operation and a first vector quantizer configured to receive a plurality of weighting signals, each representing a proportion of a computation time period for which a respective one of the unary-coded input signals should be selected by the multiplexer and to output a first selector signal to the multiplexer to cause the multiplexer to select each of the input signals in accordance with the plurality of weighting signals.

The present disclosure relates to circuitry for performing a multiply-accumulate (MAC) operation. The circuitry comprises a first multiplexer having a plurality of inputs for receiving a plurality of unary-coded input signals representing operands of the MAC operation and an output for outputting a multiplexer output signal representing a result of the MAC operation and a first vector quantizer configured to receive a plurality of weighting signals, each representing a proportion of a computation time period for which a respective one of the unary-coded input signals should be selected by the multiplexer and to output a first selector signal to the multiplexer to cause the multiplexer to select each of the input signals in accordance with the plurality of weighting signals.