In a particular implementation, a method of data conversion is disclosed. For example, for each word-line of a plurality of word-lines in a memory array, the method includes: 1) determining, by a digital comparator, if digital data exceeds a particular threshold, and 2) in response to the digital data determined to be above the threshold, transmitting, by the digital comparator, an output signal corresponding to the digital data to a digital-to-analog converter (DAC) device. Additionally, the DAC is configured to generate an analog signal.

A digital-analog conversion circuit includes an arithmetic circuit, a voltage output unit, decoders, and output lines. The arithmetic circuit receives a digital signal of multiple bits, divides the multiple bits into groups of two or more bits, and outputs a logical operation result of each group. The voltage output unit outputs voltages having different values. The decoders receive each voltage and the logical operation result, and outputs an analog signal corresponding to the digital signal. The output lines correspond to the decoders. Each decoder includes switches and selection units. The switches correspond to the voltages. Each switch alternates between output, of a corresponding voltage, to a corresponding output line and non-output, of a corresponding voltage, to a corresponding output line. The selection units correspond to the switches. The selection units receive the logical operation result, and each selection unit controls a corresponding switch based on the logical operation result.

An integrated circuit is provided that includes an output stage circuit. The output stage circuit includes an input node for receiving a digital input signal, a supply voltage node for receiving a supply voltage signal, a digital to analog convertor for converting the digital signal, an amplifier for amplifying the converted signal, a first/second and optionally third voltage regulator generating a first/second and optionally third voltage signal, and a greatest-voltage selector circuit for providing power to the amplifier. Two different voltages are provided to the DAC. The output signal can be a SENT signal. The circuit is highly robust against power-interruptions and EMI.

In a particular implementation, a method of data conversion is disclosed. For example, for each word-line of a plurality of word-lines in a memory array, the method includes: 1) determining, by a digital comparator, if digital data exceeds a particular threshold, and 2) in response to the digital data determined to be above the threshold, transmitting, by the digital comparator, an output signal corresponding to the digital data to a digital-to-analog converter (DAC) device. Additionally, the DAC is configured to generate an analog signal.

Methods and systems to implement a multiply and accumulate (MAC) unit is described. In an example, a device can include a current mode digital-to-analog converter (DAC) configured to multiply an input signal with an input current to generate a signal. The device can further include a current divider coupled to the current mode DAC. The current divider can be configured to divide the signal into at least a first current having a first amplitude and a second current having a second amplitude. The device can further include a mixer configured to multiply the second current with a clock signal to generate a third current. The third signal can be combined with the first signal via a current summing node to generate an output signal. The output signal can be outputted to another device.

A method in a transmitter circuit of generating a signal comprising a first sequence of OFDM symbols, which are to be transmitted within a frequency sub band of a second sequence of OFDM symbols is disclosed. A first cyclic prefix (CP) of the second sequence of OFDM symbols has a first duration, and a second CP of the second sequence of OFDM symbols has a second duration. In order to generate both the first and the second cyclic prefix with an integer number of equidistant samples, a first sampling rate is required. The method comprises generating the signal comprising the first sequence of OFDM symbols at a second sampling rate, lower than the first sampling rate, and adjusting a sampling phase during CPs.

The present disclosure relates to a system for exchanging signals between a device of a vehicle and an external apparatus outside the vehicle via at least one antenna of the vehicle, wherein high-frequency signals are exchanged between the at least one external apparatus and the at least one antenna of the vehicle via electromagnetic waves, wherein the at least one antenna is connected via at least one first path to a first end of a line of the vehicle, and the device is connected via at least one second path to a second end of the line of the vehicle, wherein the system has at least one frequency reduction module which is arranged along at least one of the paths, and wherein the at least one frequency reduction module is designed to adjust a value of a frequency of the high-frequency signals to a low value prior to transport along the line.

The present invention provides an analog-digital hybrid architecture, which performs 256 multiplications and additions at a time. The system comprises 256 Processing Elements (PE) (108), which are arranged in a matrix form (16 rows and 16 columns). The digital inputs (110) are converted to analog signal (114) using digital to analog converters (DAC) (102). One PE (108) produces one analog output (115) which is nothing but the multiplication of the analog input (114) and the digital weight input (112). The implementation of PE is done by using i) capacitors and switches and ii) resistor and switches. The outputs from multiple PEs (108) in a column are connected together to produce one analog MAC output (116). In the similar manner, the system produces 16 MAC outputs (118) corresponding to 16 columns. Analog to digital converters (ADC) (104) are used to convert the analog MAC output (116) to digital form (118).

A quantum circuit generator for a quantum computer includes a controller; and a plurality of analog conversion units (ACUs) operatively connected to the controller, each ACU being operatively connected to a corresponding qubit of a plurality of qubits, wherein each ACU is configured to convert a digital input from the controller into an analog input at a microwave frequency to control a quantum state of the corresponding qubit. The controller is configured to generate a quantum circuit using at least two qubits of the plurality of qubits, the at least two qubits being selected by the controller based on corresponding classical bits being mapped by the controller and based on latency of the generated quantum circuit so that the generated quantum circuit has a latency less than a threshold latency.

An integrated circuit (IC) includes a current source device configured to generate a bias current. The IC also includes a comparator, a circuit, a memory, and a digital-to-analog circuit (DAC). The comparator has a first input, a second input, and a comparator output. The first input receives a reference voltage, and the second input receives a voltage indicative of a bias current through the IC. The circuit is coupled to the comparator output. The circuit iteratively generates a final trim code based on an output signal from the comparator. The memory stores the final trim code. The DAC controls a level of the bias current through the current source device based on the final trim code.