Devices and methods for digital to analog conversion (DAC) are provided, in which the analog outputs of an even number of digital to analog converters are combined. The individual converters operate on the same data but there is a relative time delay between the input digital signal received by one or more of the converters and the input digital signal received by other of the converters, wherein the delay is a fraction of the data sample period. Moreover, the data signal fed to half of the converters has an inverse relationship with the data signal fed to the other half of the converters and their analog outputs are subtracted. Dither and filtering techniques may also be employed.

A multibit flash quantizer circuit, such as included as a portion of delta-sigma conversion circuit, can be operated in a dynamic or configurable manner. Information indicative of at least one of an ADC input slew rate or a prior quantizer output code can be used to establish a flash quantizer conversion window. Within the selected conversion window, comparators in the quantizer circuit can be made active. Comparators outside the conversion window can be made dormant, such as depowered or biased to save power. An output from such dormant converters can be preloaded and latched. In this manner, full resolution is available without requiring that all comparator circuits within the quantizer remain active at all times.

A multibit flash quantizer circuit, such as included as a portion of delta-sigma conversion circuit, can be operated in a dynamic or configurable manner. Information indicative of at least one of an ADC input slew rate or a prior quantizer output code can be used to establish a flash quantizer conversion window. Within the selected conversion window, comparators in the quantizer circuit can be made active. Comparators outside the conversion window can be made dormant, such as depowered or biased to save power. An output from such dormant converters can be preloaded and latched. In this manner, full resolution is available without requiring that all comparator circuits within the quantizer remain active at all times.

A method of converting a single-ended signal to a differential-ended signal includes the following steps: providing a first sampling capacitor having a first end and a second end; providing a second sampling capacitor having a third end and a fourth end; at a first time point, controlling the first end to receive a single-ended signal, controlling the second end to receive a reference voltage, controlling the third end to receive the reference voltage or a middle voltage value of the swing of the single-ended signal, and controlling the fourth end to receive the single-ended signal; and at a second time point, controlling the second end and the fourth end to receive the reference voltage. The first end and the third end output a differential signal after the second time point which is later than the first time point.

A method of converting a single-ended signal to a differential-ended signal includes the following steps: providing a first sampling capacitor having a first end and a second end; providing a second sampling capacitor having a third end and a fourth end; at a first time point, controlling the first end to receive a single-ended signal, controlling the second end to receive a reference voltage, controlling the third end to receive the reference voltage or a middle voltage value of the swing of the single-ended signal, and controlling the fourth end to receive the single-ended signal; and at a second time point, controlling the second end and the fourth end to receive the reference voltage. The first end and the third end output a differential signal after the second time point which is later than the first time point.

The present disclosure provides a multiplication and accumulation circuit based on radix-4 booth code and differential weight storage. The circuit includes an input data encoding circuit, a differential weight storage circuit, an integral calculation circuit and a differential ADC circuit. The input data encoding circuit is configured to encode original input data. The differential weight storage circuit is configured to store weight values, and multiply the original input data after being encoded by the weight values stored to obtain multiplication results. The integral calculation circuit is configured to respectively accumulate a positive value and a negative value of each multiplication result. The differential ADC circuit is configured to perform analog-to-digital conversion on a difference between accumulated results of the positive values and the negative values to obtain a digital multiplication and accumulation result.

The present disclosure provides a multiplication and accumulation circuit based on radix-4 booth code and differential weight storage. The circuit includes an input data encoding circuit, a differential weight storage circuit, an integral calculation circuit and a differential ADC circuit. The input data encoding circuit is configured to encode original input data. The differential weight storage circuit is configured to store weight values, and multiply the original input data after being encoded by the weight values stored to obtain multiplication results. The integral calculation circuit is configured to respectively accumulate a positive value and a negative value of each multiplication result. The differential ADC circuit is configured to perform analog-to-digital conversion on a difference between accumulated results of the positive values and the negative values to obtain a digital multiplication and accumulation result.

In accordance with an aspect of the present disclosure, a vehicle has an electric traction motor and a high voltage module having a low voltage section and a high voltage section. The low voltage section includes a power over fiber receive module and a first optical data module. A low voltage supply is electrically connected to a power over fiber transmit module. The power over fiber transmit module is optically coupled by a power over fiber cable to the power over fiber receive module of the low voltage section of the high voltage module. An electronic motor control unit includes a second optical data module that is optically coupled by an optical fiber data bus cable to the first optical data module of the low voltage section of the high voltage module.

Devices and methods for digital to analogue conversion (DAC) are provided, in which the analogue outputs of an even number of digital to analogue converters are combined. The individual converters operate on the same data but there is a relative time delay between the input digital signal received by one or more of the converters and the input digital signal received by other of the converters, wherein the delay is a fraction of the data sample period. Moreover, the data signal fed to half of the converters has an inverse relationship with the data signal fed to the other half of the converters and their analogue outputs are subtracted. Dither and filtering techniques may also be employed.

Devices and methods for digital to analogue conversion (DAC) are provided, in which the analogue outputs of an even number of digital to analogue converters are combined. The individual converters operate on the same data but there is a relative time delay between the input digital signal received by one or more of the converters and the input digital signal received by other of the converters, wherein the delay is a fraction of the data sample period. Moreover, the data signal fed to half of the converters has an inverse relationship with the data signal fed to the other half of the converters and their analogue outputs are subtracted. Dither and filtering techniques may also be employed.