Abstract: An apparatus and methods are disclosed for a bidirectional front-end circuit included within a system on chip (SoC). The bidirectional front-end circuit includes a differential bidirectional terminal for receiving and transmitting signals. The bidirectional front-end circuit is configured to provide a first communication path between a first controller and a connector through the differential bidirectional terminal when operating in a first mode. And, the bidirectional front-end circuit is reconfigured to provide a second communication path between a second controller and the connector through the differential bidirectional terminal when operating in a second mode.

Abstract: An on-chip passive transmission channel is provided for the propagation of serialized data from a first controller to a dual-protocol physical layer interface. A second controller for the dual-protocol physical layer interface is located closer on a semiconductor die to the dual-protocol physical layer interface than the first controller.

Abstract: Systems and methods for adjusting a phase step size of a clock data recover (CDR) circuit are described according to aspects of the present disclosure. In certain aspects, a method for adjusting a phase step size of a CDR circuit includes sensing a frequency offset of the CDR circuit, and adjusting the phase step size of the CDR circuit based on the sensed frequency offset. The frequency offset may be sensed by sensing a signal level on an integration path of a loop filter of the CDR circuit. The phase step size of the CDR circuit may be adjusted by switching the CDR circuit between a first phase step size and a second phase step size using a modulator (e.g., a sigma-delta modulator).

Abstract: A device, a system, a backlight module and a test method for simulating a light guide plate, the device for simulating a light guide plate includes: a light guide substrate layer; and an electroactive polymer layer, wherein the electroactive polymer layer is formed on the light guide substrate layer and is configured to produce a deformation according to a layout signal of dot-patterns to simulate the dot-patterns.

Abstract: An on-chip passive transmission channel is provided for the propagation of serialized data from a first controller to a dual-protocol physical layer interface. A second controller for the dual-protocol physical layer interface is located closer on a semiconductor die to the dual-protocol physical layer interface than the first controller.

Abstract: Aspects disclosed in the detailed description include communicating low-speed and high-speed parallel bit streams over a high-speed serial bus. In one aspect, a data transmitting circuit converts a low-speed parallel bit stream into a high-speed parallel bit stream and then serializes the converted high-speed parallel bit stream based on a high-speed reference frequency. In another aspect, a data receiving circuit recovers the low-speed parallel bit stream from the high-speed parallel bit stream if the low-speed parallel bit stream is determined to exist in the high-speed parallel bit stream.

Abstract: Power saving systems and methods for Universal Serial Bus (USB) systems are disclosed. When a USB physical layer (PHY) enters a U3 low power state, not only are normal elements powered down, but also circuitry within the USB PHY associated with detection of a low frequency periodic signal (LFPS) wake up signal is powered down. A low speed reference clock signal is still received by the USB PHY, and a medium speed clock within the USB PHY is activated once per period of the low speed reference clock signal. The medium speed clock activates the signal detection circuitry and samples a line for the LFPS. If no LFPS is detected, the signal detection circuitry and the medium speed clock return to low power until the next period of the low speed reference clock signal. If the LFPS is detected, the USB PHY returns to a U0 active power state.

Abstract: Power saving systems and methods for Universal Serial Bus (USB) systems are disclosed. When a USB physical layer (PHY) enters a U3 low power state, not only are normal elements powered down, but also circuitry within the USB PHY associated with detection of a low frequency periodic signal (LFPS) wake up signal is powered down. A low speed reference clock signal is still received by the USB PHY, and a medium speed clock within the USB PHY is activated once per period of the low speed reference clock signal. The medium speed clock activates the signal detection circuitry and samples a line for the LFPS. If no LFPS is detected, the signal detection circuitry and the medium speed clock return to low power until the next period of the low speed reference clock signal. If the LFPS is detected, the USB PHY returns to a U0 active power state.

Abstract: In one embodiment, a receiver comprises a latch configured to receive a data signal and to latch symbols of the received data signal, and a decision feedback equalizer. The decision feedback equalizer comprises a first feedback capacitor having first and second terminals, the first terminal being coupled to a first internal node of the latch. The decision feedback equalizer also comprises a first plurality of switches configured to alternatively couple the second terminal of the first feedback capacitor to a first feedback signal and a ground, the first feedback signal having a first voltage that is a function of a bit decision corresponding to a first previous symbol in the data signal preceding a current symbol in the data signal.

Abstract: A quantitative analysis method based on air pressure measuring, which can be used for the high-sensitivity quantitative detection of various targets i.e. inorganic ions, small molecules and biological macromolecules such as proteins, DNA, and even viruses, bacteria, cells, etc. The present invention catalyzes hydrogen peroxide to generate a large amount of gas using enzymes or nanoparticles, etc.; converts the target molecule detection signal into a gas pressure intensity signal; achieves signal amplification; and finally converts the pressure change into an electrical signal to conduct a reading through an air pressure meter, thereby achieving high-sensitivity quantitative detection. The feasibility, wide applicability and reliability of the present invention are certified through three different detection systems, i.e. an ELISA system, a DNA hydrogel system and a functional DNA sensor system, respectively, using an air pressure meter.

Abstract: Aspects disclosed in the detailed description include communicating low-speed and high-speed parallel bit streams over a high-speed serial bus. In one aspect, a data transmitting circuit converts a low-speed parallel bit stream into a high-speed parallel bit stream and then serializes the converted high-speed parallel bit stream based on a high-speed reference frequency. In another aspect, a data receiving circuit recovers the low-speed parallel bit stream from the high-speed parallel bit stream if the low-speed parallel bit stream is determined to exist in the high-speed parallel bit stream.

Abstract: Disclosed is a light guide plate, a back plate, an edge-lit type backlight module and a display device. The light guide plate includes a main body and an extending part, wherein the extending part is disposed on a sidewall of the main body and extending outwardly, and the extending part and the sidewall of the main body define a space for accommodating a backlight source.

Abstract: In one embodiment, a receiver comprises a latch configured to receive a data signal and to latch symbols of the received data signal, and a decision feedback equalizer. The decision feedback equalizer comprises a first feedback capacitor having first and second terminals, the first terminal being coupled to a first internal node of the latch. The decision feedback equalizer also comprises a first plurality of switches configured to alternatively couple the second terminal of the first feedback capacitor to a first feedback signal and a ground, the first feedback signal having a first voltage that is a function of a bit decision corresponding to a first previous symbol in the data signal preceding a current symbol in the data signal.

Abstract: An apparatus and methods are disclosed for a bidirectional front-end circuit included within a system on chip (SoC). The bidirectional front-end circuit includes a differential bidirectional terminal for receiving and transmitting signals. The bidirectional front-end circuit is configured to provide a first communication path between a first controller and a connector through the differential bidirectional terminal when operating in a first mode. And, the bidirectional front-end circuit is reconfigured to provide a second communication path between a second controller and the connector through the differential bidirectional terminal when operating in a second mode.

Abstract: A clock and data recovery (CDR) circuit produces an in-phase clock, a quadrature clock offset by 90 degrees from the in-phase clock, and an auxiliary clock offset from the in-phase clock by a fraction of 90 degrees. A data sampler cyclically samples a data signal to form sets of samples according to the in-phase, quadrature, and auxiliary clocks, each set comprising an in-phase sample, a quadrature sample, and an auxiliary sample. A CDR logic circuit processes the samples to form a timing word for each set.

Abstract: A phase interpolator, including: a first portion including a first plurality of branches and a plurality of tail current sources, each branch including a differential pair of transistors, source terminals of the differential pair of transistors connect to form a source node, wherein each tail current source couples to one of the source nodes, and wherein the differential pair of transistors and the corresponding tail current source are configured in a current coding scheme; a second portion including a second plurality of branches and a fixed current source coupled to the second plurality of branches, each branch of the second plurality of branches including a second plurality of differential pairs of transistors and a plurality of switches configured in a size coding scheme; wherein the first portion and the second portion are coupled to each other and to a pair of load resistors.

Abstract: An apparatus is provided. The apparatus includes a calibration circuit configured to generate a reference signal and at least one differential circuit each being configured to operate at a calibrated transconductance over process or condition variations based on the reference signal. The calibration circuit may be configured to generate the reference signal independent of the at least one differential circuit. A method for operating at least one differential circuit is provided. The method includes generating a reference signal and operating the at least one differential circuit at a calibrated transconductance or gain over process or condition variations based on the reference signal. The reference signal may be generated independently of the at least one differential circuit.

Abstract: In one embodiment, a receiver comprises a differential common-gate amplifier having a differential input and a differential output, wherein the differential input comprises a first input and a second input, and the differential common-gate amplifier is configured to amplify an input differential signal at the differential input into an amplified differential signal at the differential output. The receiver also comprises a common-mode voltage sensor configured to sense a common-mode voltage of the input differential signal, a replica circuit configured to generate a replica voltage that tracks a direct current (DC) voltage at at least one of the first and second inputs, and a comparator configured to compare the sensed common-mode voltage with the replica voltage, and to adjust a first bias voltage input to the differential common-gate amplifier based on the comparison, wherein the DC voltage depends on the first bias voltage.

Abstract: An apparatus is provided. The apparatus includes a calibration circuit configured to generate a reference signal and at least one differential circuit each being configured to operate at a calibrated transconductance over process or condition variations based on the reference signal. The calibration circuit may be configured to generate the reference signal independent of the at least one differential circuit. A method for operating at least one differential circuit is provided. The method includes generating a reference signal and operating the at least one differential circuit at a calibrated transconductance or gain over process or condition variations based on the reference signal. The reference signal may be generated independently of the at least one differential circuit.

Abstract: A phase interpolator, including: a pair of load resistors coupled to a supply voltage; a plurality of branches coupled to the pair of load resistors, each branch including a differential pair of transistors connected at source terminal to form a source node; a plurality of tail current sources, each tail current source coupled to one of the source nodes; and a plurality of coupling capacitors, each coupling capacitor coupled between the source nodes in two adjacent branches of the plurality of branches.