Class / Patent application number | Description | Number of patent applications / Date published |
326059000 | THREE OR MORE ACTIVE LEVELS (E.G., TERNARY, QUATENARY, ETC.) | 18 |
20090128190 | Implementing Logic Functions with Non-Magnitude Based Physical Phenomena - An n-valued switch with n≧2, with an input enabled to receive a signal in one of n states, an output enabled to provide a signal in one of at least 2 states, under control of a control signal having one of at least 2 states is disclosed. Signals are instances of a physical phenomenon, an instance representing a state. N-valued inverters are also disclosed. Different types of signals are disclosed, including optical signals with different wavelengths, electrical signals with different frequencies and signals represented by a presence of a material. A kit including an n-valued switch is also disclosed. | 05-21-2009 |
20090295428 | THREE-VALUED LOGIC FUNCTION CIRCUIT - There is provided a three-valued logic function circuit capable of remarkably reducing the kinds of basic circuits necessary for realizing all 3 | 12-03-2009 |
20100259297 | QUAD STATE LOGIC DESIGN METHODS, CIRCUITS, AND SYSTEMS - Quad-state logic elements and quad-state memory elements are used to reduce the wiring density of integrated circuits. The resulting reduction in wiring interconnects between memories and logic elements results in higher speed, higher density, and lower power integrated circuit designs. | 10-14-2010 |
20100321064 | COMBINATORIAL CIRCUIT WITH SHORTER DELAY WHEN INPUTS ARRIVE SEQUENTIALLY AND DELTA SIGMA MODULATOR USING THE COMBINATORIAL CIRCUIT - A combinatorial circuit with pre-calculation and having shorter delay is described. The combinatorial circuit uses information available from earlier input signals to pre-calculate intermediate signals, which are used to generate output signals when the last input signal arrives. The combinatorial circuit includes an input calculation block, at least one pre-calculation block, and an output calculation block coupled in series. The input calculation block receives some input signals and generates intermediate signals for the first pre-calculation block. The pre-calculation block(s) receive at least one earlier input signal and generate additional intermediate signals. The output calculation block receives the latest input signal and the intermediate signals from the last pre-calculation block and generates the output signals. The pre-calculation block(s) and the output calculation block may be implemented with simple circuits. In another aspect, a delta sigma (ΔΣ) modulator may use the combinatorial circuit with pre-calculation in order to improve operating speed. | 12-23-2010 |
20110121858 | BUFFER APPARATUS, INTEGRATED CIRCUIT AND METHOD OF REDUCING A PORTION OF AN OSCILLATION OF AN OUTPUT SIGNAL - A buffer apparatus for a communications bus comprises a driver circuit having an output. An amplifier circuit having an input is coupled to the output of the driver circuit. The driver circuit is arranged to generate, when in use, a drive signal having a waveform that comprises a step therein so as to substantially suppress generation by the amplifier circuit of a portion of an oscillation of an output signal. | 05-26-2011 |
20110215835 | QUAD STATE LOGIC DESIGN METHODS, CIRCUITS AND SYSTEMS - Quad-state logic elements and quad-state memory elements are used to reduce the wiring density of integrated circuits. The resulting reduction in wiring interconnects between memories and logic elements results in higher speed, higher density, and lower power integrated circuit designs. | 09-08-2011 |
20110267105 | PARITY UNIT USING 3-INPUT NANDs - Disclosed herein is a logic circuit which responds to three signals to detect whether the number of signals taking one of logic-1 and logic-0 is odd or even, and includes five NAND gates. The first NAND gate is supplied with the first signal, the second signal and the third signal; the second NAND gate is supplied with the inverted first signal, the inverted second signal and the third signal; the third NAND gate is supplied with the first signal, the inverted second signal and the inverted third signal; and the fourth NAND gate is supplied with the inverted first signal, the second signal and the inverted third signal. The fifth NAND gate is supplied with outputs of first, second, third and fourth NAND gates and produces the output signal whose logic level is dependent on whether the number of the input signals taking one of logic-1 and logic-0 is odd or even. | 11-03-2011 |
20120032701 | QUAD STATE LOGIC DESIGN METHODS, CIRCUITS, AND SYSTEMS - Quad-state logic elements and quad-state memory elements are used to reduce the wiring density of integrated circuits. The resulting reduction in wiring interconnects between memories and logic elements results in higher speed, higher density, and lower power integrated circuit designs. | 02-09-2012 |
20120133391 | CIRCUIT AND METHOD FOR ADDING DITHER TO VERTICAL DROOP COMPENSATION USING LINEAR FEEDBACK SHIFT REGISTERS - Vertical dithering is performed for vertical droop compensation in image processing using Linear Feedback Shift Registers (LFSRs). Line memories are not used. A compensation circuit includes a signature reload input signal coupled to the input of five LFSRs. Each LFSR includes a signature store. The output of each LFSR provides a sequence output signal that is gated with a corresponding enable signal in a first logic circuit. The output of all of the first logic circuits are combined in a second logic circuit to provide a control signal output. | 05-31-2012 |
20120268165 | Device and Method for Enabling Multi-Value Digital Computation and Control - Hardware and processes are provided for efficient interpretation of multi-value signals. The multi-value signals have a first voltage range with is used to indicate multiple numerical or logical values, and a second voltage range that is used to provide control functions. In one example, the multi-value circuitry is arranged as a set of rows and columns, which may be cascaded together. The control function can be implemented to cause portions of rows, columns, or cascaded connections to be powered off, thereby saving power and enabling more efficient operation. | 10-25-2012 |
20130049805 | ONE-OF-N N-NARY LOGIC IMPLEMENTATION OF A STORAGE CELL - A one-of-n storage cell for use in an N-nary dynamic logic (NDL) circuit. The storage cell may accept an input value and provide a complemented output value that corresponds to the input value. However, if an input value that corresponds to a precharge input value is received, the output value remains the previous output value. The storage cell may be implemented to accept either inverted or non-inverted one-of-n NDL signals and to provide as an output either non-inverted or inverted one-of-N NDL signals, respectively, where N is greater than two. | 02-28-2013 |
20130088260 | LATCH CIRCUIT, FLIP-FLOP CIRCUIT, AND DIVIDER - A latch circuit switches a differential operation performed by a differential operation circuit including a first logic circuit, a second logic circuit, a third logic circuit, and a fourth logic circuit and a single end operation performed by a single end operation circuit according to a logic level of an inputted selection signal. The latch circuit performs an operation to output an input signal and an inverted input signal without change from a first output terminal and a second output terminal of the latch circuit, respectively, and an operation to set the input signal and the inverted input signal in a hold state in the differential operation and performs an operation to output the input signal from the first output terminal without change and an operation to set the input signal in a hold state in the single end operation, according to a clock signal and an inverted clock signal. | 04-11-2013 |
20140240002 | VOLTAGE LEVEL CONVEROR AND RF SWITCHING DRIVER USING THE SAME - Disclosed is a voltage level converter that includes: a first conversion unit which receives at least one input signal of a logic 1 signal and a logic 0 signal from a signal input terminal and converts the signal; a second conversion unit and a third conversion unit which alternately output a logic −1 signal and the logic 1 signal respectively in accordance with the input signal; a fourth conversion unit and a fifth conversion unit which alternately output the logic −1 signal and the logic 0 signal respectively in accordance with the input signal; and a latch which has a complementary characteristic in which if a first transistor becomes an on-state, then a second transistor becomes an off-state in accordance with the input signal, and performs a positive feedback operation. A drain output of the first transistor is input to the fourth conversion unit. A drain output of the second transistor is input to the fifth conversion unit. | 08-28-2014 |
20150061727 | Analog Signal Compatible CMOS Switch as an Integrated Peripheral to a Standard Microcontroller - At least one analog signal compatible complementary metal oxide semiconductor (CMOS) switch circuit is incorporated with digital logic circuits in an integrated circuit. The integrated circuit may further comprise a digital processor and memory, e.g., microcontroller, microprocessor, digital signal processor (DSP), programmable logic array (PLA), application specific integrated circuit (ASIC), etc., for controlling operation of the at least one analog signal compatible CMOS switch for switching analog signals, e.g., audio, video, serial communications, etc. The at least one analog signal compatible CMOS switch may have first and second states, e.g., single throw “on” or “off”, or double throw common to a or b, controlled by a single digital control signal of either a logic “0” or a logic “1”. | 03-05-2015 |
20160094221 | CIRCUIT FOR LOW-POWER TERNARY DOMINO REVERSIBLE COUNTING UNIT - A circuit for a ternary Domino reversible counting unit. The circuit includes a ternary adiabatic Domino D flip-flop, a ternary adiabatic Domino positive and negative circulation port, and a ternary adiabatic Domino T-operation circuit. The ternary adiabatic Domino T-operation circuit includes a first signal input end, a second signal input end, and a third signal input end, a selection signal input end, a signal output end, a first clock signal input end, and a second clock signal input end. The positive and negative circulation port includes a signal input end, a borrow terminal, a carry terminal, a first output end, a second output end, a first clock signal input end, a second clock signal input end, and a third clock signal input end. The D flip-flop includes a signal input end, a reset terminal, a set terminal, a reverse-phase set terminal, a signal output end. | 03-31-2016 |
20160105181 | RECEIVING AN I/O SIGNAL IN MULTIPLE VOLTAGE DOMAINS - Embodiments disclosed herein include an I/O module with multiple level shifters that establish a plurality of voltage domains. Using the level shifters, the I/O module converts data signals in a core logic voltage domain to data signals in an external voltage domain. In one embodiment, when transmitting data signals to an external device, the I/O module level shifts the data signals from a core logic voltage domain to a low voltage domain. The I/O module then level shifts the data signals from the low voltage domain to an intermediate voltage domain. The I/O module may further shift the data signals from the intermediate voltage domain to both a low voltage domain and a high voltage domain. Using the data signals from both of these domains, the I/O module outputs the data signals in a voltage domain corresponding to a communication technique used to transmit data to the external device. | 04-14-2016 |
326060000 | With conversion (e.g., three level to two level, etc.) | 2 |
20090206877 | QUAD STATE LOGIC DESIGN METHODS, CIRCUITS AND SYSTEMS - Quad-state logic elements and quad-state memory elements are used to reduce the wiring density of integrated circuits. The resulting reduction in wiring interconnects between memories and logic elements results in higher speed, higher density, and lower power integrated circuit designs. | 08-20-2009 |
20090309630 | TERNARY VALVE INPUT CIRCUIT - A pull-up switching device for controlling connection and non-connection of an input terminal IN and a first supply VDD and a pull-down switching device for controlling connection and non-connection of the input terminal IN and a second supply VSS are provided. The pull-up switching device and the pull-down switching device are operated exclusively on and off in time division to hold and output the state of the input terminal during each operating state from the two output terminals. | 12-17-2009 |