A leakage compensation dynamic register, a data operation unit, a chip, a hash board, and a computing apparatus. The leakage compensation dynamic register comprises: an input terminal, an output terminal, a clock signal terminal, and an analog switch unit; a data latch unit for latching the data under control of the clock signal; and an output drive unit for inverting and outputting the data received from the data latch unit, the analog switch unit, the data latch unit, and the output drive unit being sequentially connected in series between the input terminal and the output terminal, and the analog switch unit and the data latch unit having a node therebetween, wherein the leakage compensation dynamic register further comprises a leakage compensation unit electrically connected between the node and the output terminal.

A detector slice circuit for a CT imaging system may include a plurality of sensors for detecting photons passing through an object and a first electronic component configured to determine an energy of photons detected by the plurality of sensors and generate photon count data, which may be a count of detected photons in one or more energy bins. The detector slice circuit may further include a second electronic component configured to receive the photon count data from the first electronic component and is clocked at a first clock rate; a local memory storage configured to receive the photon count data from the second electronic component at the first clock rate and to output the photon count data at a second clock rate.

A processing apparatus includes an FPGA unit connected to an oscillator configured to output a first clock, wherein the FPGA unit includes: a PLL circuit configured to output a second clock with a frequency of a predetermined ratio with respect to a frequency of the first clock and configured to output a lock signal (detection signal); an input and output monitoring unit configured to detect a ratio between the frequencies of the first clock and the second clock, compare the detected ratio with the predetermined ratio, and output an abnormal signal when the detected ratio does not coincide with the predetermined ratio; and an initialization unit configured to output a reset signal when the input and output monitoring unit outputs the abnormal signal and configured to output the reset signal when the PLL circuit outputs the lock signal.

A true random-number generator generating a random variable is provided. A first delay circuit delays an input signal to generate a first delayed signal. A second delay circuit delays the first delayed signal to generate a second delayed signal. A first sampling circuit samples the input signal according to a clock signal to generate a first sampled signal. A second sampling circuit samples the first delayed signal according to the clock signal to generate a second sampled signal. A third sampling circuit samples the second delayed signal according to the clock signal to generate a third sampled signal. An operational circuit generates the random variable and adjusts a count value according to the first sampled signal, the second sampled signal, and the third sampled signal. The operational circuit adjusts the clock signal according to the count value.

A wake-up circuit, a wake-up method and a non-transitory computer-readable storage medium are disclosed. The wake-up circuit includes a wake-up module (11) and a main control module (12). The wake-up module (11) is connected to a wake-up source and is configured to detect a wake-up signal sent by the wake-up source, and to forward the wake-up signal to the main control module (12), one or more wake-up sources being provided. The main control module (12) is connected to the wake-up module (11) and is configured to receive the forwarded wake-up signal, one main control modules (12) being provided.

Methods and apparatuses for an optimal timer array using a single reference counter are presented. According to one aspect, timers of the timer array use the single reference counter to process different timed trigger requests. A count translation logic block translates counts corresponding to the requested timed triggers to target values of the reference counter. Register arrays that include the target values and active/inactive status flags of the timers are used to implement specific timers. Comparators are used to compare values of the reference counter to the target values to establish expiration of the requested timed triggers. A target translation logic block translates a current value of the reference counter to an offset value from the target values for monitoring by an external circuit.

A true random-number generator generating a random variable is provided. A first delay circuit delays an input signal to generate a first delayed signal. A second delay circuit delays the first delayed signal to generate a second delayed signal. A first sampling circuit samples the input signal according to a clock signal to generate a first sampled signal. A second sampling circuit samples the first delayed signal according to the clock signal to generate a second sampled signal. A third sampling circuit samples the second delayed signal according to the clock signal to generate a third sampled signal. An operational circuit generates the random variable and adjusts a count value according to the first sampled signal, the second sampled signal, and the third sampled signal. The operational circuit adjusts the clock signal according to the count value.

An asynchronous multi-cycle reset synchronization circuit that can correlate any number of resets and synchronous clocks with simultaneous reset de-assertion and removal of reset assertion crossing hazards. The asynchronous multi-cycle reset synchronization circuit can also be paired with a synchronous multi-cycle reset synchronization circuit to correlate same domain asynchronous and synchronous resets. Also described is a synchronous reset multi-cycle synchronization circuit that correlates with any number of asynchronous resets and guarantees simultaneous reset de-assertion.

Methods and apparatuses for an optimal timer array using a single reference counter are presented. According to one aspect, timers of the timer array use the single reference counter to process different timed trigger requests. A count translation logic block translates counts corresponding to the requested timed triggers to target values of the reference counter. Register arrays that include the target values and active/inactive status flags of the timers are used to implement specific timers. Comparators are used to compare values of the reference counter to the target values to establish expiration of the requested timed triggers. A target translation logic block translates a current value of the reference counter to an offset value from the target values for monitoring by an external circuit.

A wake-up circuit, a wake-up method and a non-transitory computer-readable storage medium are disclosed. The wake-up circuit includes a wake-up module (11) and a main control module (12). The wake-up module (11) is connected to a wake-up source and is configured to detect a wake-up signal sent by the wake-up source, and to forward the wake-up signal to the main control module (12), one or more wake-up sources being provided. The main control module (12) is connected to the wake-up module (11) and is configured to receive the forwarded wake-up signal, one main control modules (12) being provided.