Patent application number | Description | Published |
20130147561 | DIGITALLY CONTROLLED OSCILLATOR AND DIGITAL PLL INCLUDING THE SAME - A digitally controlled oscillator has a high-order ΔΣ modulator configured to be of at least an order higher than a first order and configured to input a digital control signal and output a pseudorandom digital output signal, a first-order ΔΣ modulator configured to input the pseudorandom digital output signal and generate a control pulse signal including a pulse width corresponding to the pseudorandom digital output signal, a low pass filter configured to pass the a low frequency component of the control pulse signal, and an oscillator configured to generate a high-frequency output signal whose frequency is controlled based on the control pulse signal outputted by the low pass filter and is a frequency corresponding to the digital control signal. | 06-13-2013 |
20130335126 | CLOCK GENERATOR - A clock generator includes a delay circuit to have 2N delays, in which a delay time from a first delay of the 2N delays to a last delay is set to a length of one cycle of an input; a first phase-detector to detect a first phase-difference between the input and an output from the last delay; a first charge-pump to generate a first current according to the first phase-difference; a first loop-filter to adjust a delay amount of each of the 2N delays, based on a voltage of the first current; a second phase-detector to detect a second phase-difference between the input and an output from an Nth delay; a second charge-pump to generate a second current according to the second phase-difference; and a second loop-filter to adjust a duty ratio of an output from each of the 2N delays, based on a voltage of the second current. | 12-19-2013 |
20140055181 | CLOCK GENERATING CIRCUIT - A clock generating circuit includes: a counter that counts a number of pulses of an oscillation clock signal existed within one cycle of a reference clock signal; a first time-to-digital converter that generates a plurality of phases of first clock signals by delaying the oscillation clock signal; a second time-to-digital converter that generates a plurality of phases of second clock signals by delaying the oscillation clock signal by a short delay time; a third time-to-digital converter that generates a plurality of phases of third clock signals by delaying the delayed first clock signal; a delay control unit that outputs a delay control signal based on a difference between a cycle of the oscillation clock signal and a target cycle; and an oscillator that generates, based on a cycle of the reference clock signal, the oscillation clock signal whose cycle is 1/m of the cycle of the reference clock signal. | 02-27-2014 |
20140286457 | RECEIVER CIRCUIT AND METHOD FOR CONTROLLING RECEIVER CIRCUIT - A receiver circuit includes: a data interpolation switched capacitor circuit which samples a data signal and outputs a voltage value interpolated from a sampled voltage value in correspondence with an interpolation code indicating an interpolation ratio; a comparator which performs comparison between the voltage value outputted from the data interpolation switched capacitor circuit and a threshold value; a phase detection circuit which detects a boundary based on an output of the comparator and decides whether to advance or delay a phase; and an interpolation code generation circuit which generates an interpolation code corresponding to an output of the phase detection circuit, wherein a phase offset related to sampling is imparted and an offset corresponding to an amount of the phase offset is imparted to the threshold value of the comparator. | 09-25-2014 |
20140375486 | TIME-TO-DIGITAL CONVERTER AND CONTROL METHOD - A first switching unit configured to switch a first state for inputting a first clock signal input from a first input terminal, and a second state for inputting an output signal of a second delay element, to a first delay element. A second switching unit configured to switch a first state for inputting a second clock signal input from a second input terminal, and a second state for inputting an output signal of a first delay element, to a second delay element. After the two clock signals are respectively taken in the first delay elements and the second delay elements by putting the first and second switching units into the first state, the control unit puts the first and second switching units into the second state. An output unit outputs a phase difference obtained by decoding values stored in FFs in the second state. | 12-25-2014 |