Abstract: The present disclosure relates to an acupuncture meridian measurement system. The acupuncture meridian measurement system comprises: a signal generator configured to generate an alternating current excitation signal; an impedance measurer coupled to the signal generator and configured to measure a biological impedance between a fixed point to be measured and at least one selected point of an object; an acupuncture point determiner coupled to the impedance measurer and configured to locate an acupuncture point based on the measured biological impedance, wherein, the determined acupuncture point is a selected point, the biological impedance between which and the fixed point is less than a threshold. A technical problem solved by an embodiment of the present disclosure is to realize an accurate location of the acupuncture meridian. A use of an embodiment of the present disclosure is to locate acupuncture meridian and Yuan acupuncture points.

Abstract: A digital audio interface may include two signal inputs to transmit audio data. A first signal line may carry digital serial audio data. The second signal line may carry a word clock signal to differentiate the serial audio data transmitted over the first signal line. In the case of stereo audio data, the word clock signal may correspond to a left-right clock signal and may differentiate audio data intended for a right channel from that intended for a left channel. The audio data may also be differentiated differently depending on the configuration, such as in the case that the transmitted audio data include audio for more than two channels. The word clock signal may be scaled to regenerate a bit clock signal used to encode the serial audio data over the first signal line. The encoding bit clock signal need not be transmitted.

Abstract: Embodiments of the present invention may provide a power supply system that uses a capacitive voltage divider to selectively monitor various power supplies on an IC chip. The power supply system may sample a monitored power supply to a capacitor and select certain capacitors from a set of switched capacitors to divide down the sampled voltage. The resulting voltage may be compared to a voltage reference. Using different selections of switched capacitors, the monitored power supply may be compared for different voltage levels. The ratio of the sampling capacitor to the selected capacitors may determine a voltage level the comparator will trigger. Further, based on the monitored power supply level, the power supply system may turn on a switch between an external power supply and a regulated digital power supply to charge the regulated digital power supply while a main LDO is turned off.

Abstract: A system for time-sequential LED-string excitation includes a controller coupled to at least two LED strings and arranged to sequentially excite the strings—preferably by pulse-width modulating their respective currents—such that each string conducts a desired current and/or provides a desired light intensity. Individual string currents and/or light intensities are provided to the controller as feedback signals. The controller preferably pulse-width modulates each string such that it conducts a current which approximates the performance that would be provided if the string were made to continuously conduct an ‘optimal’ current. A voltage converter may be included to provide the supply voltage connected to the top of each LED string, and to adjust the supply voltage as needed to ensure that each string conducts a desired current.

Abstract: A sink may be to used to process multimedia digital data. The sink may include a plurality of input ports, an output port, a switchably-enabled selector to select an input port from a plurality of HDMI input ports to couple to an output port, a control circuit to detect encrypted data in a channel of the input ports; and a plurality of decryption engines. Each of the decryption engines may be coupled to respective input ports to synchronize with a corresponding encryption engine of a data source after the control circuit detects encrypted data in the channel of the respective input port. Additional circuitry may be included to operate the sink in a power saving mode. Also, methods for processing the data in both power saving and non-power saving modes.

Abstract: A detection circuit is coupled to an output terminal of a driver circuit. The detection circuit includes a comparator to compare a signal at the output terminal to a reference signal corresponding to a signal that would be generated if a capacitive load having a relatively high capacitance value were connected to the output terminal. Output of the comparator is sampled at a predetermined time after the driver circuit provides the drive signal. An error signal is generated when the sampled output indicates that the capacitive load having the relatively high capacitance value is actually connected to the output terminal.

Abstract: A digital processor and method of operation utilize an alias address space to implement variable length instruction encoding on a legacy processor. The method includes storing instructions of a code sequence in memory; generating instruction addresses of the code sequence; automatically switching between a first operating mode and a second operating mode in response to a transition in instruction addresses between a first address space and a second address space, wherein addresses in the first and second address spaces access a common memory space; in the first operating mode, accessing instructions in the first address space; in the second operating mode, accessing instructions in the second address space; and executing the accessed instructions of the code sequence. Instructions of different instruction lengths may be utilized in the first and second operating modes.

Abstract: An apparatus, system and method for controlling drive patterns is disclosed. A digital engine for controlling drive patterns may include a profile controller to program characteristics of one or more drive patterns for one or more piezoelectric actuators. The digital engine may further include a register array to store profile information for the one or more drive patterns. Each drive pattern may comprise a plurality of pulses with each pulse having a slope. The digital engine may also include a digital pattern generator to generate the one or more drive patterns based upon the profile information stored in the register array. The digital engine may further include a slope shaping circuit to modify one or more signals based upon an input from the digital pattern generator.

Abstract: An uncalibrated converter element in an analog-digital converter may be replaced with two or more smaller elements having an effective total net value that is equal to that of the uncalibrated converter element. In an exemplary case where the element is capacitor, one or more of these smaller capacitors may be independently calibrated by switching the smaller capacitor between two voltages, such as a reference voltage and ground, and then calculating a difference of corresponding digital output codes generated by the backend ADC with previously calibrated capacitors associated with lesser significant bits. The total capacitance of the uncalibrated capacitor may be apportioned between the smaller capacitors so that the individual maximum charge contribution of each smaller capacitor to the converter output together with any expected manufacturing variance does not exceed the aggregated contribution of the previously calibrated capacitors.

Abstract: A resolution detector may be used in conjunction with an ADC to identify unresolved bits in a raw digital output of the ADC. Bits that have been properly resolved by the ADC may be distinguished from those that have not been successfully resolved, because of time limitations or other reasons. Each bit that has not been successfully resolved may be classified and referred to as an unresolved bit. If there are any unresolved bits detected in a sampling cycle, dither may then be incorporated in the raw digital output to compensate for the unresolved bits in that cycle. The dither may be added to the raw digital output of the ADC to eliminate any missing codes in the processed digital output codes or the dither may be substituted for the unresolved bits in raw digital output to generate the processed digital output.

Abstract: Metal oxide semiconductor (MOS) protection circuits and methods of forming the same are disclosed. In one embodiment, an integrated circuit includes a pad, a p-type MOS (PMOS) transistor, and first and second n-type MOS (NMOS) transistors. The first NMOS transistor includes a drain, a source and a gate electrically connected to the pad, a first supply voltage, and a drain of the PMOS transistor, respectively. The second NMOS transistor includes a gate, a drain, and a source electrically connected to a bias node, a second supply voltage, and a source of the PMOS transistor, respectively. The source of the second NMOS transistor is further electrically connected to a body of the PMOS transistor so as to prevent a current flowing from the drain of the PMOS transistor to the second supply voltage through the body of PMOS transistor when a transient signal event is received on the pad.

Abstract: An approach to time domain filtering uses a passive charge sharing approach to implement an infinite impulse response filter. Delayed samples of an input signal are stored as charges on capacitors of a first array of capacitors, and delayed samples of the output signal are stored as charges on capacitors of a second array of capacitors. Outputs are determined by passively coupling capacitors of the first and second arrays to one another, and determining the output according to a total charge on the coupled capacitors. In some examples, a gain is applied to the total charge prior to storing the output on the second array of capacitors. In some examples, a charge scaling circuit is applied to the charges stored on the arrays prior to coupling capacitors to form the output.

Abstract: Apparatus and methods for demodulation are provided. In one embodiment, a method includes receiving an input signal having a frequency that varies in relation to a state of the signal, calculating a sine and cosine of a phase control signal, generating a first signal proportional to the sine of a product of a first quantity and the frequency of the input signal, generating a second signal proportional to the cosine of a product of the first quantity and the frequency of the input signal, and summing a product of the first signal and the cosine of the phase control signal with a product of the second signal and the sine of the phase control signal to generate a demodulator output for resolving the state of the input signal. In certain implementations, the phase control signal is controlled so as to reduce a frequency error of the input signal.

Abstract: The problem of inefficient channel impulse-response processing is addressed by processing different parts of a channel impulse response to accurately locate channel taps, and to generate more than one set of equalization coefficients. This allows the most-suited equalization coefficient to be selected based on a selection criterion.

Abstract: Apparatus and methods for electronic amplification are provided. In one embodiment, a method includes providing a first differential amplification block, providing a second differential amplification block, electrically connecting the first and second differential amplification blocks in a stack between a first voltage reference and a second voltage reference, amplifying a first signal using the first differential amplification block, and amplifying a second signal using the second differential amplification block. A voltage difference between the first and second voltage references defines a power supply voltage, and the first differential amplification block operates over a first range of the power supply voltage and the second differential amplification block operates over a second range of the power supply voltage.

Abstract: Methodology and circuitry for determining if a device, such as a cellular phone or personal digital assistant has been tapped is disclosed. The device includes an accelerometer and in response to an acceleration, the accelerometer outputs an acceleration signal. The accelerometer may continuously output an acceleration signal even if no acceleration occurs. A tap detection device receives the temporally sampled acceleration signal and takes the first derivative of the temporally sampled acceleration signal producing one or more derivative values. The tap detection system compares each derivative value to a threshold value and if the derivative value exceeds the threshold a tap is detected. By taking the derivative of the acceleration signal, the noise floor for the acceleration signal is reduced leading to more accurate results with less false positives and less positive negatives.

Abstract: A hearing instrument has a plurality of electronic components within a body, and an inertial sensor mechanically coupled with the body. The inertial sensor is configured to monitor the motion of the body and generate a movement signal representative of the body motion. A controller operatively coupled with the inertial sensor controls power usage by at least one or more of the electronic components as a function of the movement signal.

Abstract: A system and method for implementing a differential signaling driver with a common-mode voltage not equal to one half the power supply voltage using voltage-mode techniques. Embodiments of the present invention maintain balanced impedance at the signal output. In an embodiment, a driver may have multiple operating modes for each potential supply voltage or common-mode voltage. In an embodiment, each potential mode may involve configuring the driver by activating or deactivating switches or resistors in the driver and each potential mode may have different resistor values.

Abstract: A switch can be implemented by a switch circuit, which can include a pair of NMOS transistors connected in series as pass-through transistors to transmit an input signal at an input terminal to produce an output signal at output terminal in response to an active state of a switching signal, and a pair of PMOS transistors connected in series as pass-through transistors to transmit the input signal at the input terminal to produce the output signal at output terminal in response to the active state of the switching signal. The switch circuit can also include a switch network connecting, in response to the active state of the switching signal, sources to bodies of the pairs of NMOS and PMOS transistors, and connecting, in response to an inactive state of the switching signal, the bodies of the pair of NMOS transistors to a first reference voltage, the bodies of the pair of PMOS transistors to a second reference voltage, and the sources of the pairs of NMOS and PMOS transistors to a third reference voltage.

Abstract: Apparatus and methods for biasing amplifiers are provided. In certain implementations, a bias circuit is provided for controlling the drain-source voltage of input transistors electrically connected to the inputs of a transconductance amplification circuit. For example, the bias circuit can maintain a relatively constant drain-source voltage in the input transistors by using a feedback loop that includes a feedback amplifier for adjusting the bias current of the input transistors based upon a difference between the drain and source voltages of the input transistors. In certain implementations, the feedback amplifier has an offset voltage equal to about the desired value of the drain-source voltage, and the feedback amplifier is configured to adjust the bias current until the difference between the inputs of the feedback amplifier is equal to about the offset voltage.