Abstract: A half-rate clock and data recovery (CDR) circuit includes a first and a second gated voltage-controlled oscillators (GVCOs) and a first and a second frequency detectors. The first frequency detector generates a first output current according to a reference signal and a second divided clock, and the second frequency detector generates a second output current according to a first divided clock and the second divided clock. A loop filter converts either the first output current or the second output current to a first control voltage to control the second clock, and generates a second control voltage according to the first control voltage to control the first clock. A lock detector receives the reference signal and the second divided clock, and accordingly generates a lock signal.

Abstract: A half-rate clock and data recovery (CDR) circuit includes a first and a second gated voltage-controlled oscillators (GVCOs) and a first and a second frequency detectors. The first frequency detector generates a first output current according to a reference signal and a second divided clock, and the second frequency detector generates a second output current according to a first divided clock and the second divided clock. A loop filter converts either the first output current or the second output current to a first control voltage to control the second clock, and generates a second control voltage according to the first control voltage to control the first clock. A lock detector receives the reference signal and the second divided clock, and accordingly generates a lock signal.

Abstract: A method and a circuit for controlling an equalizer and an equalizing system are disclosed. The method includes providing a first level from a set of levels as a peaking level of the equalizer; equalizing a transmission signal by using the equalizer with the first level to obtain a first signal; providing a second level from the set of levels as the peaking level of the equalizer; equalizing the transmission signal by using the equalizer with the second level to obtain a second signal; determining a first frequency of the first signal; determining a second frequency of the second signal; comparing the first frequency and second frequency to obtain a comparing result; and determining the peaking level of the equalizer for following equalization of the transmission signal in accordance with the comparing result.

Abstract: A positioning insert for two adjacent vertebral bodies includes a plate like insert adapted to fix relative positions of the two adjacent vertebral bodies and provided with a sharp edge oppositely formed relative to the dull side and first holes defined through a side face of the plate like insert, wherein the sharp edge is formed to have an angle between 5 to 15 degrees; and an annular insert adapted to be inserted into a space between the two adjacent vertebral bodies and having second holes and a slot defined in a peripheral side face thereof to accommodate the plate like insert so as to have the plate like insert received in the slot.

Abstract: A metal-oxide-metal (MOM) capacitor able to reduce area of capacitor arrays is revealed. The MOM capacitor mainly includes at least three parallel conducting layers. Each parallel conducting layer consists of a first conductive plate, a second conductive plate disposed around the first conductive plate. There is a preset distance between the first conductive plate and the second conductive plate. The first conductive plates are electrically connected by at least one first via while the second conductive plates are electrically connected by at least one second via. Thereby, while being applied to capacitor arrays, the second conductive plates of the two adjacent MOM capacitors are connected together and shared with each other, so as to significantly reduce area of the capacitor array, improve circuit density and further optimize the layout efficiency of the chip design.

Abstract: A method for operating a SAR assisted pipelined ADC includes enabling a SAR ADC in a current stage circuit for converting an input analog voltage into a digital code during a first time interval, resetting an operational amplifier of an MDAC in the current stage circuit during the first time interval, maintaining the SAR ADC of the current stage circuit in an enabled state for outputting during a second time interval, and enabling the MDAC in the current stage circuit during the second time interval. The method also includes enabling the SAR ADC in the current stage circuit for sampling during a third time interval and connecting the output terminal of the MDAC in the current stage circuit to the input terminal of the next stage circuit during the third time interval. The first, second, and third time intervals are continuous and do not overlap each other.

Abstract: A method for operating a SAR assisted pipelined ADC includes enabling a SAR ADC in a current stage circuit for converting an input analog voltage into a digital code during a first time interval, resetting an operational amplifier of an MDAC in the current stage circuit during the first time interval, maintaining the SAR ADC of the current stage circuit in an enabled state for outputting during a second time interval, and enabling the MDAC in the current stage circuit during the second time interval. The method also includes enabling the SAR ADC in the current stage circuit for sampling during a third time interval and connecting the output terminal of the MDAC in the current stage circuit to the input terminal of the next stage circuit during the third time interval. The first, second, and third time intervals are continuous and do not overlap each other.

Abstract: A main digital-to-analog converter (DAC) receives at least one input and generates an adjusted input. A SAR unit generates a code for controlling the main DAC based on a comparison output of a comparing unit that receives the adjusted input. A reference generator, under control of the generated code, generates at least one reference voltage, which is then forwarded to the comparing unit in each corresponding cycle for defining a search range of each cycle, wherein an absolute value of the reference voltage of a latter cycle is less than the reference voltage of a former cycle such that the search range of the latter cycle is smaller than the search range of the former cycle, and search ranges of all the cycles are centered at a base voltage.

Abstract: A main digital-to-analog converter (DAC) receives at least one input and generates an adjusted input. A SAR unit generates a code for controlling the main DAC based on a comparison output of a comparing unit that receives the adjusted input. A reference generator, under control of the generated code, generates at least one reference voltage, which is then forwarded to the comparing unit in each corresponding cycle for defining a search range of each cycle, wherein an absolute value of the reference voltage of a latter cycle is less than the reference voltage of a former cycle such that the search range of the latter cycle is smaller than the search range of the former cycle, and search ranges of all the cycles are centered at a base voltage.

Abstract: A method for correcting a voltage offset influence of a pipelined analog to digital converter is disclosed, in which the method generates a first stage code and a first output voltage according to a first input voltage, generates a second stage code according to the first output voltage, generates a check code according to the first output voltage, determines a first correction code by referring to the first stage code and the check code, and corrects the first stage code with the first correction code when the first stage code is different from the first correction code.

Abstract: A SAR ADC, used for converting an analog input into an N-bit digital output in a conversion phase, includes: three comparators, each two capacitor sub-arrays, coupled to the three comparators respectively, wherein the two capacitor sub-arrays are used for sampling the analog input and providing two inputs for the corresponding comparator; and an SAR logic, coupled to the three comparators and the three capacitor arrays, for, in each conversion sub-phase, coupling two selected capacitors of each capacitor sub-array to a set of determined reference levels, coupling two capacitors, which were selected in a preceding conversion sub-phase, of each capacitor sub-array to a set of adjusted reference levels obtained based on a set of data outputted from the three comparators in a preceding conversion sub-phase, and then generating two bits of the N-bit digital output by encoding a set of data outputted from the three comparators.

Abstract: A capacitance mismatch calibrating method for a successive approximation register ADC which includes at least one array of capacitors is provided. The method includes the following steps: firstly, at least two compensating capacitors are configured. A capacitor from the array of capacitors is selected as a capacitor-under-test. Then, the terminal voltages on the terminals of the array of capacitors and on the terminals of the compensating capacitors are determined. A first comparison voltage is outputted based on the determined terminal voltages. Afterwards, a sequence of comparisons is controlled based on the first comparison voltage and a second comparison voltage to output a sequence of corresponding digital bits. Finally, a calibration value is calculated to calibrate the value of a capacitor-under-test according to the digital bits.

Abstract: A SAR ADC, used for converting an analog input into an N-bit digital output in a conversion phase, includes: three comparators, each two capacitor sub-arrays, coupled to the three comparators respectively, wherein the two capacitor sub-arrays are used for sampling the analog input and providing two inputs for the corresponding comparator; and an SAR logic, coupled to the three comparators and the three capacitor arrays, for, in each conversion sub-phase, coupling two selected capacitors of each capacitor sub-array to a set of determined reference levels, coupling two capacitors, which were selected in a preceding conversion sub-phase, of each capacitor sub-array to a set of adjusted reference levels obtained based on a set of data outputted from the three comparators in a preceding conversion sub-phase, and then generating two bits of the N-bit digital output by encoding a set of data outputted from the three comparators.

Abstract: A positioning insert for two adjacent vertebral bodies includes a plate like insert adapted to fix relative positions of the two adjacent vertebral bodies and provided with a sharp edge oppositely formed relative to the dull side and first holes defined through a side face of the plate like insert, wherein the sharp edge is formed to have an angle between 5 to 15 degrees; and an annular insert adapted to be inserted into a space between the two adjacent vertebral bodies and having second holes and a slot defined in a peripheral side face thereof to accommodate the plate like insert so as to have the plate like insert received in the slot.

Abstract: A stage of a pipeline analog-to-digital converter (ADC) is provided according to embodiments of the present invention. The stage of the present invention has double-amplifier architecture and uses level-shifting technique to generate a residue of the stage. The amplifiers of the stage are implemented in two different split paths, thereby to generate a relatively coarse amplification result and a relative fine amplification result. The relatively coarse amplification result is used to level-shift the output level of the amplifier. As a result, the stage of the present invention can have a correct residual by using amplifiers of moderate quality.

Abstract: A successive approximation register (SAR) analog-to-digital converter (ADC) is disclosed. A first and second capacitor DACs receive a first and second input signals respectively. A first coarse comparator compares an output of the first capacitor DAC with a window reference voltage, a second coarse comparator compares an output of the second capacitor DAC with the window reference voltage, and a fine comparator compares the output of the first capacitor DAC with the output of the second capacitor DAC. A SAR controller receives outputs of the first and second coarse comparators to determine whether the outputs of the first and second capacitor DACs are within a predictive window determined by the window reference voltage. The SAR controller bypasses at least one phase of analog-to-digital conversion of the SAR ADC when the outputs of the first capacitor DAC and the second capacitor DAC are determined to be within the predictive window.

Abstract: A capacitance mismatch calibrating method for a successive approximation register ADC which includes at least one array of capacitors is provided. The method includes the following steps: firstly, at least two compensating capacitors are configured. A capacitor from the array of capacitors is selected as a capacitor-under-test. Then, the terminal voltages on the terminals of the array of capacitors and on the terminals of the compensating capacitors are determined. A first comparison voltage is outputted based on the determined terminal voltages. Afterwards, a sequence of comparisons is controlled based on the first comparison voltage and a second comparison voltage to output a sequence of corresponding digital bits. Finally, a calibration value is calculated to calibrate the value of a capacitor-under-test according to the digital bits.

Abstract: A successive approximation register (SAR) analog-to-digital converter (ADC) includes a first capacitor array, a first input capacitor, a first switch module, a second capacitor array, a second input capacitor, a second switch module, a comparator and a SAR controller. The SAR ADC is operated under sampling phases and amplifying phases many times to perform amplifying operations and ADC operations upon input signals to generate digital output data. In addition, because the SAR ADC has both an amplification function and an ADC function, a circuit utilizing the SAR ADC does not require an additional active PGA, and a power consumption of the circuit is decreased.

Abstract: A successive approximation register (SAR) analog-to-digital converter (ADC) includes a first capacitor array, a first input capacitor, a first switch module, a second capacitor array, a second input capacitor, a second switch module, a comparator and a SAR controller. The SAR ADC is operated under sampling phases and amplifying phases many times to perform amplifying operations and ADC operations upon input signals to generate digital output data. In addition, because the SAR ADC has both an amplification function and an ADC function, a circuit utilizing the SAR ADC does not require an additional active PGA, and a power consumption of the circuit is decreased.

Abstract: A successive approximation register (SAR) analog-to-digital converter (ADC) is disclosed. A first and second capacitor DACs receive a first and second input signals respectively. A first coarse comparator compares an output of the first capacitor DAC with a window reference voltage, a second coarse comparator compares an output of the second capacitor DAC with the window reference voltage, and a fine comparator compares the output of the first capacitor DAC with the output of the second capacitor DAC. A SAR controller receives outputs of the first and second coarse comparators to determine whether the outputs of the first and second capacitor DACs are within a predictive window determined by the window reference voltage. The SAR controller bypasses at least one phase of analog-to-digital conversion of the SAR ADC when the outputs of the first capacitor DAC and the second capacitor DAC are determined to be within the predictive window.