Abstract: Provided is a semiconductor device capable of reducing a penalty associated with ensuring reliability. The semiconductor device includes a latch circuit which has input/output paths of three systems or more independent from each other. The latch circuit includes a plurality of storage elements STE1 to STE3 which are provided on the input/output paths of the three systems or more, respectively, and hold input data in synchronization with a clock signal. At least one storage element (for example, STE1) of the plurality of storage elements STE1 to STE3 includes a majority decision unit (for example, 81a) executing a majority decision using data from the storage elements provided on other input/output paths different from the input/output path thereof and outputs data in which a result of the majority decision is reflected.

Abstract: A buffer circuit includes a transistor cascode circuit, a latch circuit, a first transistor, a second transistor, and a voltage generator. The transistor cascode circuit is biasing at a first voltage. The latch circuit is biasing at a second voltage, whose voltage level is negative. The first transistor and the second transistor are coupling between the transistor cascode circuit and the latch circuit, and a gate of the first transistor is coupled to a gate of the second transistor. The voltage generator provides a biasing voltage to the gate of the first transistor and adjusts a voltage level of the biasing voltage dynamically according to a voltage level of the second voltage. The biasing voltage is at a first level when the buffer circuit is initially turned on, and the biasing voltage is at a second level when the buffer circuit enters the steady state.

Abstract: A method and an apparatus for wireless communication are provided. The apparatus having a first latch having a first latch input and first latch output and a second latch having a second latch input, a second latch scan output, and a second latch data output. The second latch input is coupled to the first latch output. The apparatus further includes a selection component configured to select between a data input and a scan input based on a shift input. The selection component is coupled to the first latch input. The selection component includes a first NAND-gate, a second NAND-gate, and an OR-gate.

Abstract: Some embodiments include apparatuses having input nodes to receive input signals, output nodes to provide output signals, a first stage including a first pair of input transistors, the first pair of transistors including gates coupled to the input nodes, a second stage including a second pair of input transistors, the second pair of transistors including gates coupled to the input nodes, and a third stage including inverters coupled to the output nodes. The inverters are coupled to the first and second stages at the same nodes to switch the output signals between different voltages based on the input signals.

Abstract: A level-shift circuit that operates stably is provided. The level-shift circuit has a function of boosting a first signal having an amplitude voltage between a first voltage and a second voltage to a second signal having an amplitude voltage between a third voltage and the second voltage. The level-shift circuit includes first to eighth transistors. Gates of the third and seventh transistors are electrically connected to a wiring for transmitting a third signal for controlling the amounts of current flowing into one of a source and a drain of the first transistor, one of a source and a drain of the second transistor, one of a source and a drain of the fifth transistor, and one of a source and a drain of the sixth transistor.

Abstract: A PVTM-based wide voltage range clock stretching circuit is disclosed. The circuit consists of a PVTM circuit module, a phase clock generation module, a clock synchronization selection module and a control module. The PVTM circuit module monitors in real time the delay information of an on-chip delay unit to monitor the operating environment of the circuit, and feeds the delay information back to the control module. Under the control of a clock stretching enable signal and a clock stretching extent signal, the control module selects a target phase clock from the clocks generated by the phase clock generation module in accordance with the feedback from the PVTM, enabling the stretching of system clock within a single cycle in different PVT conditions. Sophisticated gate devices are not required, and the cost of area and power consumption are kept to minimal.

Abstract: The invention proposes a method for distributing a signal to each block Bj of a series of N adjacent blocks of identical design in an electronic circuit. It proposes, in an identical fashion for each of the N blocks, placing a timing delay circuit MUX-DELj on the path for conveying a signal Sc from the input INcj of the block to an internal electrical node Ndj of the block for this signal Sc; providing for the timing delay circuit to supply N delayed signals corresponding to N different timing delays ?f1, . . . ?fj, . . . ?fN separated by an increment of elementary duration ?t that corresponds to the elementary delay ?t for transit of a block introduced into a conductive line; and selecting the delayed signal corresponding to the applicable timing delay according to the block in question, by means of an index signal propagated through the N blocks, and which is incremented or decremented on passage through each block.

Abstract: A peak detector including an input circuit with five same-sized transistors, in which four of the input transistors are coupled in parallel between a control node and a bias node and receive a corresponding one of two in-phase signals and two quadrature signals. The fifth transistor is coupled between a current node and the bias node and has its control terminal coupled to an output node. A bias circuit establishes a predetermined bias current that flows through the five input transistors. A current mirror mirrors the current through the fifth transistor from the current terminal into the four parallel-coupled input transistors via the control node. An output circuit charges a peak capacitor based on voltage developed at the control terminal of the fifth transistor. The peak detector is low power and compact and detects the actual peak of the input signal with greater accuracy compared to a conventional peak detector.

Abstract: A duty cycle correction circuit includes a charge pump and a controller. The charge pump includes a current source, a first output, and a second output. The charge pump routes current from the current source to the first output during a positive portion of a clock, and routes current from the current source to the second output during a negative portion of the clock. The controller compares charge accumulated from the first output to charge accumulated from the second output over a plurality of clock cycles to determine which of the positive portion of the clock and the negative portion of the clock is longer. The controller also generates a digital value that indicates an amount of adjustment to apply to a duty cycle of the clock based on which of the positive portion of the clock and the negative portion of the clock is longer.

Abstract: Various methods and devices that involve pulsed signals are disclosed. An example minimum pulse-width (MPW) circuit comprises a first and second logic circuit. A first input of the first logic circuit is connected to an input of the MPW circuit. A first input of the second logic circuit is communicatively coupled to an output of the first logic circuit. The MPW circuit also comprises a MPW filter circuit communicatively coupled to an output of the second logic circuit, a one-shot circuit communicatively coupled to an output of the minimum pulse-width filter circuit and located on a first feedback path, and another one-shot circuit communicatively coupled to the output of the minimum pulse-width filter circuit and located on a second feedback path. A second input of the first logic circuit is on the first feedback path. A second input of the second logic circuit is on the second feedback path.

Abstract: An integrated circuit for saturation detection comprises: a plurality of gain components; a plurality of saturation detectors with each saturation detector operably coupled to an output of one of the gain components; a plurality of logic elements with a first input of each logic element associated with an output of one of the saturation detectors; and a controller operably coupled to the plurality of logic elements. The controller is arranged to apply a signal to a second input of individual ones of the plurality of logic elements such that an output of the respective logic element identifies a saturation event of the saturation detector associated with that respective logic element.

Abstract: A transmitter includes: an output driver that outputs differential signals to differential signal lines; first termination resistors and a first switch which are provided in series between a first reference voltage input terminal to which a reference voltage is inputted and the differential signal lines; a pulse generator that outputs a common-mode pulse to the differential signal lines; a second switch provided between the differential signal lines and the pulse generator; a detector that detects, after generation of the common-mode pulse starts, timing at which a voltage level of the common-mode pulse exceeds a threshold; and a controller that places the second switch in an on state to connect the pulse generator to the differential signal lines, and powers down the output driver and then places the first switch in an off state to allow the pulse generator to output the common-mode pulse to the differential signal lines.

Abstract: A method of differential signal transfer from a differential input Vinp and Vinn having a common mode input voltage that can be higher than the power supply voltage by providing an input chopper having first through fourth chopper transistors, each having a source, a drain and a gate, the input chopper having Vinp and Vinn as a differential input, providing an output chopper, capacitively coupling a differential output Voutp and Voutn of the input chopper to a differential input of the output chopper, capacitively coupling a clock to the input chopper and coupling the clock to the output chopper, the clock having a first phase and a second phase opposite from the first phase, the first phase being coupled to the gates of the first and second transistors and the second phase being coupled to the gates of the third and fourth transistors, and providing protection of the gates of the first through fourth transistors from excessive voltages. Various embodiments are disclosed.

Abstract: A drive circuit for driving a semiconductor switch includes an overload detector circuit connected to the semiconductor switch and designed to detect an overload state of the semiconductor switch. The drive circuit further includes a driver circuit connected to a control terminal of the semiconductor switch and designed to generate, upon detection of an overload state, a driver signal having a level such that the semiconductor switch is switched off or switch-on is prevented. The driver circuit is further designed to generate a driver signal for driving the semiconductor switch according to a control signal, wherein for switching on the transistor at a first instant a driver signal is generated at a first level and, if no overload state is detected up to a predefined time period having elapsed, the level of the driver signal is increased to a second level.

Abstract: To provide a semiconductor device in which external correction can be performed, the area occupied by a read circuit is reduced, and power consumption is reduced. One embodiment of the semiconductor device includes a pixel and a read circuit. The pixel includes a transistor and a display element. The read circuit includes a function selection portion and an operational amplifier. The transistor is electrically connected to the function selection portion through a wiring. The operational amplifier is electrically connected to the function selection portion. The function selection portion includes at least one switch. The function selection portion can select a function of the read circuit by controlling the switch.

Abstract: According to one embodiment, a semiconductor device includes: a first switch SWx which switches whether or not to supply a first power supply voltage Vx generated by accumulating a charge outputted from a power source 10, as a second power supply voltage VDD to a first circuit 13, and a second switch SW1 which switches whether or not to connect to the first circuit 13 a smoothing capacitor C1 which suppresses a fluctuation of the second power supply voltage VDD, and the first switch SWx is switched to an on state in response to that the first power supply voltage Vx has reached a sufficient voltage, and then the second switch SW1 is switched to the on state in response to that the second power supply voltage VDD has reached a sufficient voltage.

Abstract: To operate a load a half bridge includes a switching device with a high-side semiconductor switch and a low-side semiconductor switch. The semiconductor switches are connected in series via their current terminals, and each semiconductor switch may be assigned, via its control terminal, a driving system that switches the respective semiconductor switch on or off according to a drive signal. The load is connectable between the high-side and low-side semiconductor switches. The half bridge may include a load relief device connected to the switching device, e.g., in order to collect energy during a switching process in the switching device. The half bridge can\include an energy recovery circuit configured to feed the energy collected by the load relief device, e.g., a current, to an energy storage device before a further energy collection, e.g., current collection, of the load relief device, during a further switching process in the switching device.

Abstract: An embodiment of a device includes a terminal, an active transistor die electrically coupled to the terminal, a detector configured to sense a signal characteristic on the terminal, and control circuitry electrically coupled to the active transistor die and to the detector, wherein the active transistor die, detector, and control circuitry are coupled to a package. The control circuitry may include a control element and a control device. Based on the signal characteristic, the control circuitry controls which of multiple operating states the device operates. A method for controlling the operating state of the device includes sensing, using the detector, a signal characteristic at the terminal, and determining, using the control device, whether the signal characteristic conforms to a pre-set criteria, and when the signal characteristic does not conform to the pre-set criteria, modifying the state of the control element to alter the operating state of the device.

Abstract: Various implementations described herein are directed to a circuit. The circuit may include a memory circuit having a first latch. The circuit may include a power-on-reset circuit having a second latch coupled to the first latch. The second latch may be configured to reset the first latch to a predetermined state at power-up.

Abstract: Systems, circuits, and methods for operating an Insulated-Gate Bipolar Transistor (IGBT) are provided. A circuit is to include a first driver for the IGBT, the first driver having a first resistance and being connectable to the gate of the IGBT. The circuit is further described to include a second driver for the IGBT, the second driver having a second resistance different from the first resistance and also being connectable to the gate of the IGBT. The circuit is also described to include a controller that receives at least two inputs regarding operating characteristics of the IGBT and based on the at least two inputs decides whether to connect the first or second driver to the gate of the IGBT during power-down of the IGBT.

Abstract: A solid state power control apparatus includes: (a) at least one IGBT and at least one FET, for supplying current to a load, and (b) a current controller for shutting off the IGBT and FET. The current controller is arranged to start shut off of the IGBT before it starts shut off of the FET. Further, the current controller is arranged to reduce current flow prior to start of the turn off of the IGBT and FET.

Abstract: To generate an analog current without restriction by a power supply voltage. A semiconductor device includes a first node, a second node, a first- to an n-th-stage power storage element (n is an integer greater than or equal to 2), and a first- to an n-th-stage switch. The capacities of the first- to the n-th-stage power storage element are different from one another. The first- to the n-th-stage power storage element are electrically connected in parallel between the first node and the second node. A first terminal of a k-th stage power storage element (k is an integer greater than or equal to 1 and less than or equal to n) is electrically connected to the first input node via a k-th stage switch. The on/off states of the first- to the n-th-stage switch are controlled by a first to an n-th signal.

Abstract: A control circuit and a terminal are provided. The control circuit includes a detector, a current-voltage conversion circuit and a control signal generation circuit. The current output end of the detector is connected with the current input end of the current-voltage conversion circuit. The voltage output end of the current-voltage conversion circuit is connected with the voltage input end of the control signal generation circuit. The signal input end of the control signal generation circuit outputs a control signal. The detector detects a state of motion of a detected object and generates at least one current signal according to the state of motion of the detected object. The current-voltage conversion circuit converts the at least one current signal transmitted by the detector to at least one voltage signal.

Abstract: Arrangement for controlling a component having multiple states includes a device that generates a signal at a frequency that enables it to be conducted through a human body, and a conductive surface coupled to the device, situated in a position accessible by a part of the human, and which enables proximity or contact of the part of the human to the conductive surface to develop a reactive coupling between the human and the conductive surface. The component has multiple, different states and is controlled by the human to change from a first state to a second state upon completion of an electrical circuit including the component, the conductive surface and the device upon developing reactive coupling between the human and the conductive surface when the device is generating the signal conducted through the human. The component may be a vehicular component such as a door or window.

Abstract: Described herein are a method and an apparatus for dynamically switching between one or more finite termination impedance value settings to a memory input-output (I/O) interface of a memory in response to a termination signal level. The method comprises: setting a first termination impedance value setting for a termination unit of an input-output (I/O) interface of a memory; assigning the first termination impedance value setting to the termination unit when the memory is not being accessed; and switching from the first termination impedance value setting to a second termination impedance value setting in response to a termination signal level.

Abstract: In illustrative embodiments disclosed herein, a logic element may be provided on the basis of a non-volatile storage mechanism, such as ferroelectric transistor elements, wherein the functional behavior may be adjusted or programmed on the basis of a shift of threshold voltages. To this end, a P-type transistor element and an N-type transistor element may be connected in parallel, while a ferroelectric material may be used so as to establish a first polarization state resulting in a first functional behavior and a second polarization state resulting in a second different functional behavior. For example, the logic element may enable a switching between P-type transistor behavior and N-type transistor behavior depending on the polarization state.

Abstract: Disclosed herein is a driver circuit including a first group of transistors provided between first and second nodes and including n of the transistor(s) where n is equal to or greater than one, and a second group of transistors provided in parallel with the first group of transistors and including m of the transistor(s) where m is equal to or greater than one and not equal to n, the m transistors being connected together in series. The n-channel transistor in the first group and at least one of the two n-channel transistors in the second group have their gate connected to an input node.

Abstract: In accordance with some embodiments, the present disclosure relates to a dual mode control interface that can be used to provide both a radio frequency front end (RFFE) serial interface and a two-mode general purpose input/output (GPIO) interface within a single digital control interface die. In certain embodiments, the dual mode control interface, or digital control interface, can communicate with a power amplifier. Further, the dual mode control interface can be used to set the mode of the power amplifier.

Abstract: A semiconductor circuit includes a first circuit and a second circuit. The first circuit is configured to generate a voltage level at a first node based on a voltage level of input data, an inverted value of the voltage level at the first node, a voltage level of a clock signal, and a voltage level at a second node; and the second circuit is configured to generate the voltage level at the second node based on the voltage level of input data, an inverted value of the voltage level at the second node, the voltage level of the clock signal, and the inverted value of the voltage level at the first node. When the clock signal is at a first level, the first and second nodes have different logical levels. When the clock signal is at a second level, the first and second nodes have the same logical level.

Abstract: A method of configuring a programmable integrated circuit device to implement control flow at a current basic block. A branch selector node within the current basic block is configured to receive at least one control signal, where each of the at least one control signal is associated with a respective previous basic block. The branch selector node is further configured to select one of the at least one control signal based on one or more intended destinations for the at least one control signal, and provide the selected control signal to a data selector node within the current basic block. The data selector node is configured to select a data signal based on the selected control signal, where the selected data signal is from the respective previous basic block that is associated with the selected control signal.

Abstract: An integrated circuit enables the selection of a circuit. According to one implementation, a plurality of redundant circuits provide a predetermined function and a voltage sensor may be coupled to receive a reference voltage. A selection circuit may be coupled to the voltage sensor and the reference voltage, wherein the selection circuit selects one of the plurality of redundant circuits to be implemented in the integrated circuit based upon a detected voltage of the reference voltage of the reference voltage.

Abstract: A semiconductor device detects an edge of input data input into a data retention circuit to which a clock signal is supplied, resets a first count value obtained by counting an edge detection frequency with a clock signal, resets a second count value obtained by counting the edge detection frequency with an inverted clock signal, and thereby detects an abnormality of the clock signal in accordance with a situation that either of the first count value and the second count value has reached a value indicative of an overflow state.

Abstract: A system may include a sampling circuit, a temperature calibration system, a phase detector, a virtual phase-locked loop, and a sample rate converter. The sampling circuit may be configured to generate a series of digitally-sampled data at a sampling frequency provided by a local clock. The temperature calibration system may be configured to determine a temperature-based timing compensation with respect to the local clock. The phase detector may be configured to estimate an error of the local clock in view of the reference clock. The virtual phase-locked loop may be configured to generate a virtual clock based on the temperature-based timing compensation and the error. The sample rate converter may be configured to generate a corrected series of digitally-sampled data in response to the virtual clock by interpolating the series of digitally-sampled data to correct for the error.

Abstract: Adaptive clocking schemes for synchronized on-chip functional blocks are provided. The clocking schemes enable synchronous clocking which can be adapted according to changes in signal path propagation delay due temperature, process, and voltage variations, for example. In embodiments, the clocking schemes allow for the capacity utilization of a logic path to be increased.

Abstract: A clock generation circuit may include a reference clock generator configured to generate a pair of first reference clocks in an offset code generation mode, a correction code generator configured to generate a reference correction code according to a duty detection signal based on a phase difference between the pair of first reference clocks, and an offset code generator configured to generate an offset code based on the reference correction code and a preset reference code.

Abstract: A stacked synthesizer for wide local oscillator (LO) generation using a dynamic divider. The phase locked loop can include a plurality of voltage controlled oscillators (VCOs), and a selector that can be configured to select an output of one of the plurality of VCOs. The selected output of one of the plurality of VCOs can be provided to an on-chip dynamic divider and to an off-chip dynamic divider for LO sharing. The dynamic dividers can be configured to generate synthesizer outputs based on a multiplication of the selected output of one of the plurality of VCOs by a factor (1+1/M), where M is a variable number.

Abstract: An atom cell is provided with an internal space including a space formed of a through hole housing gaseous alkali metal, a space formed of a through hole housing a compound as an alkali metal emission material, and a space formed of a through hole housing liquid or solid alkali metal.

Abstract: An analog to digital converter (ADC) circuit includes a first stage for converting a first analog voltage signal to a first digital signal including a first portion of a digital output signal representing the first analog voltage signal, and generate a first residue voltage based on the first analog voltage signal and the first digital signal. A first amplifier control unit generates a first amplifier start signal based on a second stage ready signal indicating that a second stage is ready to process a second analog voltage signal. In response to the second stage ready signal, a first amplifier generates the second analog voltage signal based on the first residue voltage. The second stage is configured to generate the second stage ready signal, receive the second analog voltage signal, and convert the second analog voltage signal to a second digital signal including a second portion of the digital output signal.

Abstract: In an analog-to-digital converter (ADC) having storage capacitors, active, top-plate, n-type, switch circuitry has an n-type transistor and gate-voltage control circuitry that generates the gate voltage to turn on and off the transistor. The control circuitry turns off the transistor by generating the gate voltage at a level that limits the gate-to-source voltage difference, thereby limiting GISL leakage current through the transistor that can otherwise jeopardize the accuracy of the ADC digital output value. In one implementation, when the transistor is to be off (for example, during the ADC conversion phase), the control circuitry generates the gate voltage to be at ground if the source voltage is below a reference voltage, and above ground if the source voltage is above the reference voltage. The switch circuitry can also be implemented using a p-type device or a transmission gate instead of the n-type device.

Abstract: In a semiconductor device, a sine wave signal is input to a first input part and a cosine wave signal is input to a second input part. A multiplexer alternately selects one of the sine wave signal and the cosine wave signal. An analog to digital converter converts the output signal of the multiplexer into a digital value. A switching circuit is coupled between at least one of the first and second input parts and the multiplexer. The switching circuit is configured to be able to invert the input sine wave signal or the input cosine wave signal, in order to reduce the angle detection error due to the non-linearity error of the A/D converter.

Abstract: A multi-zone digital-to-analog device is provided with a digital-to-analog (D/A) stage having an input to accept a digital input signal with a data bandwidth of M Hertz (Hz), a clock input to accept a clock signal with a clock frequency of P Hz, and an output to supply an analog value having a bandwidth of M Hz. An upsampling stage has an input to accept the analog value and a clock input to accept the clock signal. The upsampling stage has a device bandwidth of L Hz to supply an analog output signal with a full power bandwidth of K Hz, where (P/2)=M and M<K<L. The upsampling stage supplies analog output signal images in a plurality of Nyquist zones. In one aspect, the D/A stage supplies N deinterleaved analog values having a combined bandwidth of M Hz, where N×(P/2)=M.

Abstract: A digital to analog converter (DAC) circuit includes pulse generator circuit for generating voltage pulses having a predetermined length and shape. The voltage pulses are used to control the generation of current pulses generated by a voltage to current converter. The voltage to current converter includes a set of switchable resistors where the resistance value provided by the set is dependent upon a digital value of a digital signal. In some embodiments, the current amplitude of the current pulses is dependent upon the resistance value and is indicative of the digital value.

Abstract: Disclosed are systems and methods for identifying and reporting failures of an analog-to-digital converter (ADC). Specifically, the systems and methods described herein evaluate quantization noise properties of ADCs, including delta-sigma ADCs and successive approximation register (SAR) ADCs, to verify functionality and/or identify failures. Quantization noise properties can be evaluated in the frequency domain by, for example, comparing RMS values, magnitudes, frequency spectrums, and the like, in various frequency bands to threshold values and/or to verify an expected noise shape. Quantization noise properties can additionally or alternatively be evaluated in the time domain by, for example, comparing counts of pulse widths, average pulse widths, and/or number of transitions within a sequence of pulses to threshold values and/or to similar identifiable characteristics in other pulse width bands.

Abstract: A sigma-delta modulator arrangement includes a continuous-time sigma-delta modulator with at least one modulator stage, a digital integrator and a given number of switches. The switches are arranged and configured to convert the continuous-time sigma-delta modulator into a first order incremental sigma-delta analog-to-digital converter comprising the digital integrator. At least a first modulator stage of the continuous-time sigma-delta-modulator, which is coupled with an input of the continuous-time sigma-delta modulator, includes at least one tuning element for adjusting an input signal and/or a feedback signal which are supplied to the first modulator stage.

Abstract: Described is an analog to digital converter (ADC) which comprises: a sigma-delta modulator to receive an analog signal, the sigma-delta modulator operable to perform chopping to cancel common-mode noise; and one or more counters coupled to the sigma-delta modulator to generate a digital code representative of the analog signal.

Abstract: An integrated circuit device can include at least one input; at least one output configured to provide a multi-bit output value; at least one input; at least one output configured to provide a multi-bit output value; a plurality of configurable digital filter circuits; and switch circuits coupled to the at least one input and to the at least one output, the switch circuits configurable to connect same digital filter circuits as a single processing path or separate processing paths.

Abstract: Technologies for efficiently compressing data with run detection include a compute device. The compute device is to produce a hash as a function of a symbol at a present position and a predefined number of symbols after the present position in an input stream, determine whether the symbol at the present position is part of a run, obtain, from a hash table, a chain of pointers to previous positions in the input stream associated with the hash, determine, as a function of whether the symbol is part of a run and to identify a matched string, a number of strings referenced by the chain of pointers to compare to a string associated with the present position in the input stream, and output, in response to an identification of a matched string, a reference to the matched string in a set of compressed output data.

Abstract: Data compression using a combination of content independent data compression and content dependent data compression. In one aspect, a system for compressing data comprises: a processor, and a plurality of data compression encoders wherein at least one data encoder utilizes asymmetric data compression. The processor is configured to determine one or more parameters, attributes, or values of the data within at least a portion of a data block containing either video or audio data, to select one or more data compression encoders from the plurality of data compression encoders based upon the determined one or more parameters, attributes, or values of the data and a throughput of a communications channel, and to perform data compression with the selected one or more data compression encoders on at least the portion of the data block.

Abstract: A method for performing parallel coding with ordered entropy slices includes: providing a plurality of entropy slices to a plurality of processing elements, wherein each entropy slice includes a plurality of blocks; initializing CABAC states of a current entropy slice as the CABAC states of a previous entropy slice after processing DB blocks of the previous entropy slice. DB is a positive integer.

Abstract: Techniques are described for optimizing a parity-check matrix for a low density parity check (LDPC) encoder. In an example, a first parity-check matrix is accessed. Based on a set of rules, an independent set of check nodes and variable nodes is determined. The set of rules specifies that a check node associated with the first parity-check matrix belongs to the independent set when the check node is connected to only one variable node from the independent set. The set of rules further specifies that a variable node associated with the first parity-check matrix belongs to the independent set when the variable node is connected to only one check node from the independent set. A size of the independent set is based on the set of rules. A second parity-check matrix is generated by at least applying a permutation to the first parity-check matrix based on the independent set.