Abstract: The processing of information is performed using a magneto-optic circuit that modifies the polarization of light using the Kerr effect. Magneto-optic circuits perform digital-to-analog conversion, comparison of values, and mathematical operations. Current carrying wires pass near a fiber-optic that carries polarized light. Each individual wire contributes a modification to the polarization of the light based on the current carried in each wire. The modified light is passed through a polarizer, and the intensity of the light may be measured with a photodiode to produce an electrical signal representing a result.

Abstract: A frequency ratio measurement device includes a counter section configured to count a time event of a first signal and output a count value obtained by multiplying the time event by k0, a time to digital converter section configured to output a time digital value corresponding to a phase difference between the first signal and a second signal, a combiner section configured to output a combined value of the count value and the time digital value, a subtractor section configured to output a difference value between a first value based on the combined value and a second value, a quantizer section configured to compare a third value based on the difference value with a predetermined threshold to thereby output a quantized value obtained by quantizing the third value, and a feedback section configured to output, based on a time event of the second signal, the second value based on the quantized value.

Abstract: Provided is a planar multipole antenna, and more particularly, to a planar multipole antenna which is capable of adjusting a beam width and a band characteristic and reducing the size. The planar multipole antenna includes a plurality of radiators formed above a conductor plate, the plurality of radiator includes a main radiator and a plurality of additional radiators, the main radiator includes a signal applying hole to which a signal is applied, and the additional radiator is connected to a ground formed on the conductor plate.

Abstract: In a system for converting digital data into a modulated optical signal, an electrically controllable device having M actuating electrodes provides an optical signal that is modulated in response to binary voltages applied to the actuating electrodes. A digital-to-digital converter provides a mapping of input data words to binary actuation vectors of M bits and supplies the binary actuation vectors as M bits of binary actuation voltages to the M actuating electrodes, where M is larger than the number of bits in each input data word. The digital-to-digital converter maps each digital input data word to a binary actuation vector by selecting a binary actuation vector from a subset of binary actuation vectors available to represent each of the input data words.

Abstract: A compact connector for transmitting super-high-frequency signals is adapted to connect a printed circuit board (PCB) to a single or multiple high-frequency signal lines transmitting super-high frequency signals therethrough. The compact connector includes: a male connector connected to the single or multiple super-high frequency signal lines and including a male connector housing receiving, securing, and protecting terminals of the single or multiple super-high frequency signal lines; and a connector socket mounted on the PCB and receiving the male connector housing fastened to the male connector, wherein the super high-frequency signal line terminals in the male connector are brought into direct contact with and connected to signal line terminal pads formed on the printed circuit board, respectively.

Abstract: Digital to analog conversion generates an analog output corresponding to a digital input by controlling unit elements or cells using data bits of the digital input. The unit elements or cells individually make a contribution to the analog output. Due to process, voltage, and temperature variations, the unit elements or cells may have mismatches and/or errors. The mismatches and/or errors can degrade the quality of the analog output. To extract the mismatches and/or errors, a transparent dither can be used. The mismatches and/or errors can be extracted by observing the analog output, and performing a cross-correlation of the observed output with a switching bit stream of the dither. Once extracted, the unit elements or cells can be adjusted accordingly to reduce the respective mismatches and/or errors.

Abstract: An analog-to-digital converting system and a method with offset correction mechanisms are provided. The method includes steps of: obtaining a direct current offset of an output voltage of a digital analog conversion unit in a system; obtaining first capacitance weights and second capacitance weights sequentially from small to large; subtracting the direct current offset from a digital signal; and multiplying bit values of the digital signal respectively by the corresponding first capacitance weight value or second capacitance weight value to output a decode signal.

Abstract: To speed up decoding of a range code. A decompression circuit calculates a plurality of candidate bit values for each bit of the N-bit string based on a plurality of possible bit histories of a bit before a K-th bit in parallel for a plurality of bits, and repeatedly selects a correct bit value of the K-th bit from the plurality of candidate bit values based on a correct bit history of the bit before the K-th bit to decode the N-bit string.

Abstract: An antenna assembly is provided for an electronic device. The electronic device has a housing, which includes a first portion and a second portion, the first portion is electrically conductive, and the second portion is non-conductive. The antenna assembly includes an antenna cavity, at least two antennas located in the antenna cavity, and at least one isolation structure. The antennas are used for radiating energy, the isolation structure is disposed between the two antennas and connected to the two antennas, and the isolation structure isolates induced currents of the two antennas to reduce interference at a same frequency or from adjacent frequency channels between the two antennas.

Abstract: An encoding apparatus for encoding a vibrotactile signal includes a first transforming unit configured to perform a discrete wavelet transform of the signal, a second transforming unit configured to generate a frequency domain representation of the signal, a psychohaptic model unit configured to generate at least one quantization control signal based on the generated frequency domain representation of the sampled signal and on a predetermined perceptual model based on human haptic perception, a quantization unit configured to quantize wavelet coefficients resulting from the performed discrete wavelet transform and adapted by the quantization control signal, a compression unit configured to compress the quantized wavelet coefficients, and a bitstream generating unit configured to generate a bitstream corresponding to the encoded signal based on the compressed quantized wavelet coefficients.

Abstract: An antenna apparatus is provided, including: a substrate extending in a substrate plane, wherein the substrate includes a first side and an opposite second side, wherein a first antenna is arranged on the first side of the substrate, and a three-dimensional shape structure arranged on the first side and extending out of the substrate plane and across the first antenna so that the first antenna is arranged between the substrate and the three-dimensional shape structure. In addition, a second antenna is arranged on the three-dimensional shape structure.

Abstract: Systems, apparatus and methods are provided for decompressing compressed data. A method may include receiving encoded data to be decompressed, obtaining a “Stotal” of a total number of symbols, numbers of occurrences for distinct symbols in the encoded data, and a final state generated during an encoding process as a first state for decoding, building a decoding table containing a row of the distinct symbols, a row of substitutes for numbers of bits to be recovered and a row of substitutes for new states corresponding to encoding states, decoding using the decoding table including: obtaining a current symbol from the decoding table based on a current state X, dynamically determining a current number of bits to be recovered from the encoded data and a new state X based on corresponding substitutes and outputting symbols recovered. L may be a sum of the numbers of occurrences for the distinct symbols.

Abstract: A digital-to-analog conversion device and a digital-to-analog conversion system with multiple digital-to-analog conversion cores is provided. At least some of the multiple digital-to-analog conversion cores may be operated with different clock signals, especially with clock signals of different clock frequencies. For this purpose, each digital-to-analog conversion stage is provided with multiple different clock signals and each stage individually selects one of the multiple clock signals.

Abstract: Systems, apparatus and methods are provided for compressing data and decompressing compressed data. A method may include receiving encoded data to be decompressed, obtaining a size “Stotal” of a total number of symbols in the encoded data, numbers of occurrences for distinct symbols in the encoded data, a number L of sum of the numbers of occurrences for the distinct symbols, and a final state generated during an encoding process as a first state for decoding, building a decoding table containing the distinct symbols corresponding to L encoding states, decoding the encoded data using the decoding table including: obtaining a current symbol from the decoding table based on a current state X, dynamically determining a current number of bits to be recovered from the encoded data and a new state X, and outputting symbols recovered from the encoded data.

Abstract: Patch antennas include four radiation elements arrayed in a rectangular lattice pattern at four positions around a feeding point in the electrode, and wiring which electrically couples each of the radiation elements and the feeding point with an equal wiring length, and is fed by a line-shaped feeding conductor arranged at a position intersecting slots formed at a ground conductor plate, where the feeding conductor has a repetitive branch pattern in which multiple pieces of line-shaped wiring are connected in T-shapes being perpendicular to each other at a total of 2N?1 branch points from a base end to each of the tips, and each of the tips is bent in a same direction in the second direction from a terminal end of the line-shaped wiring to which the tip is connected.

Abstract: Analog to digital conversion errors caused by non-linearities or other sources of distortion in an analog-to-digital converter are compensated for by use of a machine learning system, such as a neural network. The machine learning system is trained based on simulation or measurement data, which utilizes a filtered output of the analog-to-digital converter that has less distortion errors than the unfiltered output of the analog-to-digital converter. The effect on the analog to digital conversion errors by Process-Voltage-Temperature parameters may be incorporated into the training of the machine learning system.

Abstract: Devices, methods, and systems for encoding data as DNA are provided. An encoder device can include an encoder engine configured to encode a data file having a bit sequence encoding data and further configured to generate a virtual DNA (VDNA) sequence of virtual nucleotide bases (Vnb) that reversibly encodes the bit sequence of the data file, divide the VDNA sequence into a plurality of VDNA fragments, associate each VDNA fragment with an archive library sequence (Arc_SEQ), and generate a read instruction (READ) sequence of differences between each VDNA fragment and each associated Arc_SEQ including sufficient instruction to facilitate regeneration of each VDNA fragment from each associated Arc_SEQ. A codeword sequence (Code_SEQ) is additionally generated for each VDNA fragment comprising a codename identifying the associated Arc_SEQ, the READ sequence associated with the VDNA fragment, and an index sequence (Idx_SEQ) including an index mapping of the VDNA fragment in the VDNA sequence.

Abstract: A common antenna assembly and a common antenna structure are provided. The common antenna assembly includes a substrate, a plurality of patch antenna disposed on the substrate, a matching network disposed on the plurality of patch antennas, and a plurality of phase shifters electrically connected to the matching network. The substrate defines a first direction and a second direction that are perpendicular to each other. The patch antennas are defined into a plurality of antenna units. Each of the antenna units has four of the patch antennas. In each of the antenna units along the first direction, any one of the antenna units shares a longitudinal common antenna unit with each of the adjacent antenna units. In each of the antenna units along the second direction, any one of the antenna units shares a horizontal common antenna unit with each of the adjacent antenna units.

Abstract: An analog-to-digital converter (ADC) is provided. The ADC receives an analog input signal and generates a digital code. The ADC includes a sigma-delta modulator (SDM), a decimation filter and a detection circuit. The SDM includes a loop filter, a quantizer and a digital-to-analog converter (DAC). The loop filter receives the analog input signal. The quantizer is coupled to the loop filter and quantizes an output of the loop filter to generate a digital output signal. The DAC is coupled to the quantizer and the loop filter. The decimation filter is coupled to the SDM and converts the digital output signal into the digital code. The detection circuit is coupled to the SDM and detects a node voltage of the SDM and generate a control signal. The control signal is utilized to control the loop filter, the quantizer, a feedback path of the SDM and/or a feedforward path of the SDM.

Abstract: An antenna array may include shielding elements that provide a degree of radiation shielding to other components of the antenna array, such as a substrate of the antenna array. In some examples, the shielding elements may be positioned to overlap with one or more gaps between antenna elements, or one or more gaps between ground elements (e.g., when viewed from a radiation source, when viewed in a direction perpendicular to a substrate). Thus, shielding elements of an antenna array may reflect, absorb, or otherwise dissipate radiation that passes through such gaps before the radiation is incident on the other components of the antenna array, such as the substrate of the antenna array.