Abstract: Embodiments of the disclosure provide a differential clock duty cycle correction (DCC) circuit, including: a hybrid current injector including current sources for generating a correction current, wherein the correction current is added to a clock signal of a first polarity at a first correction node and subtracted from a clock signal of an opposite polarity at a second correction node, and wherein a plurality of the current sources in the hybrid current injector are controlled by a first portion of a n-bit DAC code to generate the correction current; and a current DAC for receiving a second, different portion of the n-bit DAC code and for outputting a corresponding reference current to the current sources in the hybrid current injector, wherein the current sources generate the correction current in response to the reference current output by the current DAC for the second portion of the n-bit DAC code.

Abstract: Embodiments of the disclosure provide a differential clock duty cycle correction (DCC) circuit, including: a hybrid current injector including current sources for generating a correction current, wherein the correction current is added to a clock signal of a first polarity at a first correction node and subtracted from a clock signal of an opposite polarity at a second correction node, and wherein a plurality of the current sources in the hybrid current injector are controlled by a first portion of a n-bit DAC code to generate the correction current; and a current DAC for receiving a second, different portion of the n-bit DAC code and for outputting a corresponding reference current to the current sources in the hybrid current injector, wherein the current sources generate the correction current in response to the reference current output by the current DAC for the second portion of the n-bit DAC code.

Abstract: A high-definition multimedia interface circuit uses a high-definition multimedia interface encoder to produce a plurality of channels of data. An output circuit, connected to the high-definition multimedia interface encoder, produces a plurality of channels of high frequency data from the data produced by the high-definition multimedia interface encoder. A multiplexer selects a channel for sampling, and a capacitive coupler capacitively couples the multiplexer to a sampling circuit. The sampling circuit produces sampled data corresponding to the high frequency data having a clock rate less than a clock rate of the high frequency data. A test circuit compares the sampled data with the data produced by the high-definition multimedia interface encoder.

Abstract: A high-definition multimedia interface circuit uses a high-definition multimedia interface encoder to produce a plurality of channels of data. An output circuit, connected to the high-definition multimedia interface encoder, produces a plurality of channels of high frequency data from the data produced by the high-definition multimedia interface encoder. A multiplexer selects a channel for sampling, and a capacitive coupler capacitively couples the multiplexer to a sampling circuit. The sampling circuit produces sampled data corresponding to the high frequency data having a clock rate less than a clock rate of the high frequency data. A test circuit compares the sampled data with the data produced by the high-definition multimedia interface encoder.

Abstract: A high-definition multimedia interface circuit uses a high-definition multimedia interface encoder to produce a plurality of channels of data. An output circuit, connected to the high-definition multimedia interface encoder, produces a plurality of channels of high frequency data from the data produced by the high-definition multimedia interface encoder. A multiplexer selects a channel for sampling, and a capacitive coupler capacitively couples the multiplexer to a sampling circuit. The sampling circuit produces sampled data corresponding to the high frequency data having a clock rate less than a clock rate of the high frequency data. A test circuit compares the sampled data with the data produced by the high-definition multimedia interface encoder.

Abstract: A phase/frequency detector includes two D-Q flip-flops, an OR gate, and an exclusive NOR (XNOR) gate. The phase/frequency detector is used in conjunction with a clock dejitter PLL where the underflow and overflow flags from a FIFO are coupled to the inputs of the OR gate and the Q outputs of the flip-flops are coupled to the inputs of the XNOR gate. The Qb output of each flip-flop is coupled to the D input of the respective flip-flop. The recovered clock signal is coupled to the clock input of the first flip-flop and the output of the VCXO is coupled to the clock input of the second flip-flop. The SET input of the first flip-flop is coupled to the overflow flag and the RESET input of the first flip-flop is coupled to the underflow flag. The SET input of the second flip-flop is coupled to the output of the OR gate and the output of the XNOR gate is passed through the filter to the input of the VCXO.

Abstract: An apparatus for correcting imperfectly equalized bipolar signals includes a delay line having a reset control, an AND gate, and a one-shot multivibrator. The apparatus is used in conjunction with an adaptive equalizer with the output of the adaptive equalizer being coupled to the input of the apparatus of the invention. More particularly, the output of the equalizer is coupled to the input and reset of the delay as well as to one input of the AND gate. The output of the delay line is coupled to the other input of the AND gate. The output of the AND gate is coupled to the input of the one-shot multivibrator and the output of the one-shot multivibrator is the corrected signal. The delay line is approximately equal to the pulse width of an erroneous pulse which is expected from over-equalization. When the delayed signal is compared to the original signal via the AND gate, narrow pulses are removed from the signal.

Abstract: Described is a CMOS circuit arrangement with precise balanced, differential switch points. The circuit arrangement includes a voltage-follower which forces a reference voltage across an on-chip reference resistor. The current which is generated is mirrored and is made to flow through a plurality of on-chip resistors. The mirrored current flowing through the plurality of resistors generate a plurality of proportional reference voltages. Two of the proportional reference voltages are used to set the switching threshold to one input of a comparator whose output is fed back to control a switch which selects one of the two voltages. Another one of the proportional reference voltages is coupled to another input of the comparator. The circuit arrangement forms a hysteresis circuit if positive and negative thresholds are chosen.