Abstract: The present disclosure provides a receiver. The receiver comprises an antenna, configured to receive a received signal on a downlink direction, wherein the received signal comprises an interfering downlink signal and a desired downlink signal; and a detecting circuit, coupled to the antenna, configured to perform a multiuser detection operation on the received signal on the downlink direction to generate a detected interfering signal and a detected desired signal; wherein the desired downlink signal is transmitted by a first station, intended for the receiver, and generated according to a first modulation order; wherein the interfering downlink signal is transmitted by a second station, intended for a second receiver other than the receiver, and generated according to a second modulation order.

Abstract: The present invention provides a decision feedback equalizer including a first path and a second path. The first path includes a first sampling circuit and a first latch circuit, wherein the first sampling circuit generates a first set signal and a first reset signal according to an input signal, a second set signal and a second reset signal, and the first latch circuit generates a first digital signal according to the first set signal and the first reset signal. The second path includes a second sampling circuit and a second latch circuit, wherein the second sampling circuit generates the second set signal and the second reset signal according to the input signal, the first set signal and the first reset signal, and the second latch circuit generates a second digital signal according to the second set signal and the second reset signal.

Abstract: This invention discloses a memory card access module and a memory card access method. The memory card access method is applied to an electronic device. A processing unit of the electronic device accesses a memory card through a memory card slot. The method includes steps of: detecting whether the memory card supports a Peripheral Component Interconnect Express (PCIe) interface; when the memory card does not support the PCIe interface, controlling the processing unit to access the memory card through a first data transmission path and performing data format conversion between a transmission interface and the PCIe interface using a memory card access unit disposed on the first data transmission path; and when the memory card supports the PCIe interface, controlling the processing unit to access the memory card through a second data transmission path that allows the processing unit and the memory card to transmit data through the PCIe interface.

Abstract: Disclosed is a symbol timing determining device including: a symbol timing detecting circuit detecting a reception signal to obtain a first symbol timing, and shifting the first symbol timing to obtain a second symbol timing; an estimation signal generating circuit processing the reception signal according to the first and the second symbol timings respectively, so as to obtain a first and a second channel estimation frequency-domain signals; a channel estimation impulse response signal generating circuit generating a first and a second channel estimation impulse response time-domain signals according to the first and the second channel estimation frequency-domain signals respectively; a power measuring circuit measuring the energy of the first and the second channel estimation impulse response time-domain signals according to a predetermined signal region respectively; and a decision circuit selecting one of the first and the second symbol timings according to a relation of the measured energy.

Abstract: The present invention discloses an electrostatic discharge (ESD) protection circuit including: a first terminal configured to provide a first voltage having a first value in a normal mode; a second terminal configured to provide a second voltage having a second value in the normal mode; a detection circuit configured to provide a detection voltage according to the first and second voltages; and a protection circuit configured to operate in one of the normal mode and an ESD mode according to the detection voltage. When the difference between a value of the detection voltage and an average of the first and second values reaches a predetermined threshold, the protection circuit enters the ESD mode from the normal mode, and thereby has a first path between the first terminal and a grounding terminal and/or a second path between the second terminal and the grounding terminal be conductive for discharging abnormal energy.

Abstract: A multi-member Bluetooth device includes: a main Bluetooth circuit capable of bidirectionally communicating with a remote Bluetooth device through a first Bluetooth communication circuit; and an auxiliary Bluetooth circuit capable of communicating with the main Bluetooth circuit through a data transmission circuit. While the main Bluetooth circuit utilizes the first Bluetooth communication circuit to communicate with the remote Bluetooth device, the auxiliary Bluetooth circuit utilizes a second Bluetooth communication circuit to sniff packets transmitted from the remote Bluetooth device. When detected that the auxiliary Bluetooth circuit has missed packets transmitted from the remote Bluetooth device, the main Bluetooth circuit transmits missing packets of the auxiliary Bluetooth circuit to the auxiliary Bluetooth circuit through the data transmission circuit.

Abstract: Disclosed is a DDR SDRAM physical layer interface circuit including: a multiphase clock generator generating a plurality of clocks including a reference clock, a first clock, a second clock and a third clock; a frequency dividing circuit generating a PHY clock according to the first clock; a clock output path outputting the reference clock to a storage circuit; a first output circuit outputting a first output signal to the storage circuit according to a first input signal of a memory controller, the first clock and the PHY clock; a second output circuit outputting a second output signal to the storage circuit according to a second input signal of the memory controller, the second clock and the PHY clock; and a third output circuit outputting a third output signal to the storage circuit according to a third input signal of the memory controller, the third clock and the PHY clock.

Abstract: A data bit width converter is adapted to: convert first data using a first bit width as a data segment unit and second data using a second bit width as a data segment unit, and provide a cache to temporarily store third data, wherein the first bit width is not equal to the second bit width. The data bit width converter includes a slave, a cache, and a data reconstitution circuit. The slave is configured to read and write the second data. The cache is configured to read and write the third data. The data reconstitution circuit is configured to: convert the first data and the second data, and sequentially search the cache and the slave for the second data according to a searching program, to output the first data, and write the third data to the cache according to a temporary storage program.

Abstract: An integrated circuit structure includes a substrate, an integrated inductor, multiple components, multiple metal interconnections, a first shielding structure, and a second shielding structure. The integrated inductor is substantially formed in a first layer of the integrated circuit structure. The metal interconnections are coupled to the integrated inductor and the components. The first shielding structure is formed between the first layer and the substrate and is substantially beneath the integrated inductor. The second shielding structure is formed between the first layer and the substrate, has substantially the same distribution as the metal interconnections, and is substantially beneath the metal interconnections. The first shielding structure and the second shielding structure are equipotential.

Abstract: A chip includes one or more function input pads, a sequence generation circuit, one or more logic circuits, one or more scan chains, a selection circuit, and one or more sequence output pads. The function input pad is configured to receive a function sequence. The sequence generation circuit is configured to generate a diagnosis sequence. The logic circuit includes a plurality of logic gates, for responding to the function sequence and outputting one or more logic results. When enabled by the selection circuit, the scan chain outputs a response result in response to the logic result or a diagnosis result in response to the diagnosis sequence. The sequence output pad receives the diagnosis result when the scan chain responds to the diagnosis sequence.

Abstract: The present invention discloses a mixer bias circuit including a first reference voltage generation circuit, an amplifier, a first transistor array, a first switch array, a second reference voltage generation circuit, a second transistor array, a second switch array, a first resistive component, and a second resistive component. The mixer bias circuit provides multiple bias voltages by dynamically tracking the common mode voltage of a trans-impedance amplifier (TIA) and compensates for imbalance and mismatch effects by asymmetrically trimming the bias voltages to improve the second-order intercept point of a radio frequency (RF) receiver front-end (RXFE).

Abstract: A comparator circuit is applied to comparing an input voltage and a reference voltage to generate a comparison result. The comparator circuit includes a resistor circuit, a current source circuit and a transistor switching circuit. The resistor circuit receives first and second input voltages in the input voltage. The current source circuit provides a first current and a second current, and the first current, the second current and the resistor circuit generate the reference voltage. The transistor switching circuit generates the comparison result at its output end according to a first control voltage and a second control voltage at its input end. The current source circuit and the resistor circuit generate the first control voltage according to the first current and the first input voltage, and generate the second control voltage according to the second current and the second input voltage.

Abstract: A transmitting-end Bluetooth device and a receiving-end Bluetooth device of a Bluetooth communication system is disclosed. The transmitting-end Bluetooth device is arranged to operably insert an auto-pairing request and a source Bluetooth device address into one or more target packets when the transmitting-end Bluetooth device wants to initiate a Bluetooth auto-pairing procedure, and arranged to operably transmit the one or more target packets when operating under a transmitting-end predetermined operating mode. The receiving-end Bluetooth device is arranged to operably receive the one or more target packets when operating under a receiving-end predetermined operating mode, and to parse the one or more target packets to extract the auto-pairing request and the source Bluetooth device address from the one or more target packets.

Abstract: A USB adapting circuit is suitable for being connected between a USB host and an external device. The USB adapting circuit includes a connecting port, a detecting circuit, a standby circuit and a main circuit. The standby circuit receives a power supply from the USB host and supplies the detecting circuit and the main circuit with the power supply. The detecting circuit is configured to output a connected signal when the external device is connected to the connecting port. The standby circuit outputs an enabling signal in response to the connected signal. The main circuit adapts between the USB host and the external device when receiving the enabling signal. Therefore, the main circuit does not work without receiving the enabling signal, and has a power saving effect.

Abstract: A successive approximation register (SAR) analog-to-digital converter (ADC) and a method of operating the SAR ADC are provided. The SAR ADC converts an analog input signal into a digital code and includes a switch-capacitor digital-to-analog converter (DAC), and the switch-capacitor DAC includes multiple capacitors. The method includes the steps of: switching terminal voltage(s) of at least one target capacitor among the capacitors according to a data in a sampling phase; sampling the analog input signal in the sampling phase; switching the terminal voltage(s) of the at least one target capacitor after the sampling phase; comparing the outputs of the switch-capacitor DAC to obtain multiple comparison results that constitute the digital code; and switching the terminal voltages of a part of the capacitors according to the comparison results.

Abstract: A clock generation system having a time and frequency division activation mechanism is provided that includes a clock source processing circuit that generates a primary clock signal and clock-branching circuits that perform a clock-branching generation procedure respectively in an order. Each of the clock-branching modules includes a frequency division unit and a processing unit. The frequency division unit receives the primary clock signal to divide the frequency according to a divisor number and output a branch clock signal. The processing unit controls the frequency division unit to not output the branch clock signal before the clock-branching generation procedure and to decrease the divisor number gradually over time period after the clock-branching generation procedure begins such that a branch frequency of the branch clock signal generated by the frequency division unit increases from an initial frequency to a final frequency to finish the clock-branching generation procedure.

Abstract: An audio signal processing method and an audio equalizer, both implemented in an embedded system without incurring excessive computation, use a Kaiser-Bessel-derived (KBD) window and an Overlap-and-Add (OLA) processing to eliminate signal distortion of a time domain audio signal during signal conversion and to generate filters according to audio effects desired by a user.

Abstract: Clock adjustment circuits and clock adjustment methods are provided. The clock adjustment circuit is configured to generate an output clock and includes a phase interpolator, a logic circuit, and an integrator. The phase interpolator is configured to generate by interpolation an intermediate clock according to a first reference clock, a second reference clock, and a control signal. The frequencies of the first reference clock, the second reference clock and the intermediate clock are substantially the same. The logic circuit is coupled to the phase interpolator and configured to generate the output clock according to the intermediate clock and one of the first reference clock and the second reference clock. The integrator is coupled to the phase interpolator and the logic circuit and configured to generate the control signal according to the output clock. The control signal varies with an average based on a duty cycle of the output clock.

Abstract: A data bit width converter is adapted to: convert first data using a first bit width as a data segment unit and second data using a second bit width as a data segment unit, and provide a cache to temporarily store third data, wherein the first bit width is not equal to the second bit width. The data bit width converter includes a slave, a cache, and a data reconstitution circuit. The slave is configured to read and write the second data. The cache is configured to read and write the third data. The data reconstitution circuit is configured to: convert the first data and the second data, and sequentially search the cache and the slave for the second data according to a searching program, to output the first data, and write the third data to the cache according to a temporary storage program.

Abstract: Disclosed is a function-expandable wired network device using an external circuit to execute an operation an Ethernet device can't execute. The wired network device includes an Ethernet switch and a Field-Programmable Gate Array (FPGA). The switch includes Ethernet ports including a designated port and a first port, and receives a first packet from the first port; and if the first packet carries information meeting the information prestored in the switch, the switch amends the first packet to output a second packet to the designated port. The FPGA receives the second packet from the designated port and processes the second packet according to the switch's amendment to the second packet so as to output a third packet to the designated port. The switch then processes the third packet according to the FPGA's amendment to the third packet to output a fourth packet to one of the Ethernet ports.