A circuit includes a first digital controlled oscillator and a second digital controlled oscillator coupled to the first digital controlled oscillator. A skew detector is connected to determine a skew between outputs of the first digital controlled oscillator and the second digital controlled oscillator, and a decoder is utilized to output a control signal, based on the skew, to modify a frequency of the first digital controlled oscillator using a switched capacitor array to reduce or eliminate the skew. A differential pulse injection oscillator circuit and a pulse injection signal generator circuit are also provided,

The invention provides a dynamic D flip-flop, and a data operation unit, a chip, a hash board and a computing device using the same. The dynamic D flip-flop comprises: an input terminal, an output terminal and at least one clock signal terminal; a first latch unit for transmitting data of the input terminal and latching the data under control of a clock signal; a second latch unit for latching data of the output terminal and inversely transmitting the data latched by the first latch unit under control of a clock signal; and an output driving unit for inverting and outputting the data received from the second latch unit; wherein the second latch unit outputs in high level, low level and high impedance states by means of a single element under control of a clock signal. Therefore, the invention can effectively reduce chip area, power consumption, and logic delay.

The invention provides a dynamic D flip-flop, and a data operation unit, a chip, a hash board and a computing device using the same. The dynamic D flip-flop comprises: an input terminal, an output terminal and at least one clock signal terminal; a first latch unit for transmitting data of the input terminal and latching the data under control of a clock signal; a second latch unit for latching data of the output terminal and inversely transmitting the data latched by the first latch unit under control of a clock signal; and an output driving unit for inverting and outputting the data received from the second latch unit; wherein the second latch unit outputs in high level, low level and high impedance states by means of a single element under control of a clock signal. Therefore, the invention can effectively reduce chip area, power consumption, and logic delay.

According to one aspect of embodiments, a driver circuit having an overcurrent protection function includes a control signal generating circuit that outputs a Pulse Width Modulation (PWM) control signal for controlling turning ON and OFF of the output transistor that supplies output current to a load; and a control circuit that generates a signal indicating an overcurrent state when a count value of an overcurrent detecting signal exceeds a predetermined number, which indicates that a value of an output current of the output transistor within the predetermined time interval exceeds a predetermined threshold value.

According to one aspect of embodiments, a driver circuit having an overcurrent protection function includes a control signal generating circuit that outputs a Pulse Width Modulation (PWM) control signal for controlling turning ON and OFF of the output transistor that supplies output current to a load; and a control circuit that generates a signal indicating an overcurrent state when a count value of an overcurrent detecting signal exceeds a predetermined number, which indicates that a value of an output current of the output transistor within the predetermined time interval exceeds a predetermined threshold value.

A semiconductor integrated circuit of an embodiment includes: a delay element array circuit in which a plurality of delay elements having a delay amount Tw are connected in series; a flip-flop group including a plurality of flip-flops each of which an input is connected to an output of a corresponding delay element; a delay element group configured to generate, from an input clock signal, a plurality of output clock signals each having a delay difference of a second delay amount smaller than the delay amount Tw; and a delay unit configured to set a third delay amount smaller than the second delay amount, and the delay element group and the delay unit are connected in series between an output terminal of an input signal CLK_DET and an input terminal of the flip-flop group.

A semiconductor integrated circuit of an embodiment includes: a delay element array circuit in which a plurality of delay elements having a delay amount Tw are connected in series; a flip-flop group including a plurality of flip-flops each of which an input is connected to an output of a corresponding delay element; a delay element group configured to generate, from an input clock signal, a plurality of output clock signals each having a delay difference of a second delay amount smaller than the delay amount Tw; and a delay unit configured to set a third delay amount smaller than the second delay amount, and the delay element group and the delay unit are connected in series between an output terminal of an input signal CLK_DET and an input terminal of the flip-flop group.

A duty cycle correction circuit, and method of operating the same, to correct the duty cycle of an input clock signal having a frequency divided-down from a reference clock by an odd-valued integer. A delay stage outputs the input clock signal delayed by one half-cycle of the reference clock, and a logic circuit outputs an extended clock signal by a logical OR of the input and delayed clock signals. A latch latches the extended clock signal when enabled by the reference clock, and a flip-flop latches the extended clock signal responsive to the reference clock. A gate selects the latch output or the flip-flop output based on the state of the delayed clock signal as an intermediate signal. A multiplexer generates the output clock by selecting between the intermediate signal and the input clock signal in alternating reference clock phases.

A duty cycle correction circuit, and method of operating the same, to correct the duty cycle of an input clock signal having a frequency divided-down from a reference clock by an odd-valued integer. A delay stage outputs the input clock signal delayed by one half-cycle of the reference clock, and a logic circuit outputs an extended clock signal by a logical OR of the input and delayed clock signals. A latch latches the extended clock signal when enabled by the reference clock, and a flip-flop latches the extended clock signal responsive to the reference clock. A gate selects the latch output or the flip-flop output based on the state of the delayed clock signal as an intermediate signal. A multiplexer generates the output clock by selecting between the intermediate signal and the input clock signal in alternating reference clock phases.

The invention provides a dynamic D flip-flop, and a data operation unit, a chip, a hash board and a computing device using the same. The dynamic D flip-flop comprises: an input terminal, an output terminal and at least one clock signal terminal; a latch unit for latching data of the input terminal and inversely transmitting the data under control of a clock signal; and an output driving unit for inverting and outputting the data received from the latch unit; wherein the latch unit outputs in high level, low level and high impedance states by means of a single element under control of a clock signal. Therefore, the invention can effectively reduce chip area, power consumption, and logic delay.