Abstract: Disclosed is a micro-electro-mechanical switch, including a substrate having a gate connection, a source connection, a drain connection and a switch structure, coupled to the substrate. The switch structure includes a beam member, an anchor, an anchor beam interface and a hinge. The beam member having a length sufficient to overhang both the gate connection and the drain connection. The anchor coupling the switch structure to the substrate. The anchor beam interface coupling the anchor to the hinge. The hinge coupling the beam member to the anchor at a respective position along the anchor's length, the hinge to flex in response to a voltage differential established between the gate and the beam member. The switch structure having gaps between the substrate and the anchor in regions proximate to the hinges.

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: A pipeline stage of a pipelined analog-to-digital converter (ADC) circuit can include an ADC to convert an analog input to a digital output, a first plurality of digital-to-analog converters (DACs) sufficient in number to produce an analog output corresponding to the digital output, and a second plurality of DACs configured to have their output added into the analog output, where a succeeding pipeline portion can convert the amplified analog residue to at least one second digital output and a digitized residue. A mapping circuit can selectively exchange inputs between a selected one of the first plurality of DACs and one of the second plurality of DACs, and a calibration signal circuit can provide first and second calibration signals to inputs of the selected one of the first plurality of DACs and another of the second plurality of DACs.

Abstract: An analog-to-digital converter includes a plurality of sequentially cascaded stages, each stage including an amplifier and four copies of a circuit block including a flash and capacitors, in which the four copies of the circuit block operate interleavingly in a respective sample mode, pre-gain mode, gain mode, and reset mode of the circuit block, the copies of the circuit block in the sample mode, pre-gain mode, and reset mode are decoupled from the amplifier, and the copy of the circuit block in the gain mode is coupled to the amplifier to produce an output for a next following stage.

Abstract: An amplifier includes an amplifier section having selectable signal paths to provide discrete gain settings, and logic to incrementally select the signal paths. The logic may be configured to increment the gain in response to digital gain control signals or an analog gain control signal. Another amplifier has an input section with one or more input cells and an output section with one or more output cells. Either the input section or the output section includes at least two cells that may be selected to provide discrete gain settings. A loop amplifier is configured in a feedback arrangement with the input section. The input and output sections may have multiple selectable cells to provide coarse and fine gain steps. The gain of the loop amplifier may be coordinated with the gain of the input section to provide constant bandwidth operation.

Abstract: A MEMS microphone has a base, a backplate, and a backplate spring suspending the backplate from the base. The microphone also has a diaphragm forming a variable capacitor with the backplate.

Abstract: A system for correcting programming failures in an M-bit primary array of programmable fuses. The address of the failed fuse is stored in a secondary fuse array. Correction logic coupled to the primary and secondary arrays propagates the programming states of the good fuses, and corrects the programming state of the failed fuse, if any. The correction logic preferably comprises a decoder coupled to the secondary array which produces a one-hot M-bit word representing the failed fuse, and combinatorial logic arranged to receive the programming states of the primary array fuses and the one-hot M-bit word at respective inputs and to produce the correction logic output. Multiple failures can be accommodated using multiple secondary arrays, each storing the address of a respective failed fuse, or a tertiary array which stores the address of a failed fuse in either the primary or secondary arrays.

Abstract: An I/Q imbalance compensation block of a RF receiver for compensating an imbalance between an in-phase component and a quadrature component of an RF signal is disclosed. The compensation block includes a conjugation block; an adaptive finite impulse response (FIR) filter; and an adder. The filter use filter coefficients iteratively updated at least partly in response to a compensated digital signal. The filter can have a complex number for at least one, but not all of filter taps, and real numbers for other filter taps. The filter can be provided with adaptation step sizes different from filter tap to filter tap. The filter can also be provided with an adaptation step size(s) varying over time. The filter can also be provided with an adaptation step size(s) divided by the square norm of the compensated signal.

Abstract: A method of forming a MEMS device provides first and second wafers, where at least one of the first and second wafers has a two-dimensional array of MEMS devices. The method deposits a layer of first germanium onto the first wafer, and a layer of aluminum-germanium alloy onto the second wafer. To deposit the alloy, the method deposits a layer of aluminum onto the second wafer and then a layer of second germanium to the second wafer. Specifically, the layer of second germanium is deposited on the layer of aluminum. Next, the method brings the first wafer into contact with the second wafer so that the first germanium in the aluminum-germanium alloy contacts the second germanium. The wafers then are heated when the first and second germanium are in contact, and cooled to form a plurality of conductive hermetic seal rings about the plurality of the MEMS devices.

Abstract: A bias-shaping circuit for adjusting power consumption in a frequency divider to a temperature-dependent minimum includes a temperature-dependent bias source for producing a temperature-dependent bias. The bias is combined with an input signal to create an output bias. The output bias changes in response to a change in temperature to compensate for at least a portion of a temperature-induced change in the frequency divider, thereby adjusting power consumption in the frequency divider to a temperature-dependent minimum.

Abstract: A microphone is formed to have a diaphragm that is configured to improve signal to noise ratio. To that end, the microphone has a backplate having a hole therethrough, and a diaphragm movably coupled with the backplate. The diaphragm has a bottom surface (facing the backplate) with a convex portion aligned with the hole in the backplate.

Abstract: A bipolar transistor comprising an emitter region, a base region and a collector region, and a guard region spaced from and surrounding the base. The guard region can be formed in the same steps that form the base, and can serve to spread out the depletion layer in operation.

Abstract: A process allows for the modification of the least-means-square (LMS) algorithm to remove perturbations associated with measured signals in an analog-to-digital converter (ADC). The process includes measuring the perturbations and determining a coefficient associated with the perturbations. The LMS algorithm is modified in accordance with whether a digital or an analog correction of the inter-stage error of a residue amplifier on the ADC is to be made.

Abstract: Image rejection calibration includes initializing the calibration mode by applying to quadrature mixers, in place of the wanted RF input, an RF source in the frequency range of the wanted RF input, sensing the power output from the poly-phase filter, developing gain adjust and phase adjust correction values in response to the power output and adjusting in accordance with the correction values the gain of the quadrature signals from the quadrature mixers to the poly-phase filter and the phase of local oscillator quadrature signals from the local oscillator to the quadrature mixers to reduce the power output.

Abstract: Transmitter signals are modulated with one or more codes which may represent a pulse even though the code(s) are not shaped as pulses. The code(s) may be generated by defining a pulse by its Fourier components, and then adding random phases to the Fourier components. A time-domain signal may then be created, which may serve as the code to be modulated on a carrier wave. Upon reflection of the transmitter signal, the received signal may be processed by a receiver to recover the pulse. The time-of-flight of the transmitter signal can then be determined, enabling distance measurements to be made.

Abstract: An auto-zero amplifier includes a main amplifier for amplifying an input signal; the main amplifier receives an offset-correction signal for cancelling an offset at a first common-mode level of the input signal. At the first common-mode level, the offset-correction signal is based on a first value stored using a first offset-storage element. When a change is detected in the input common-mode from the first level to a second level, the first offset-storage element is switched out and a second offset-storage element, having a second value based on the second common-mode level, is switched in.

Abstract: Apparatus and methods reduce common-mode error. An integrated circuit includes a plurality of signal channels, a first proxy channel, and a subtraction block. The signal channels are configured to receive a plurality of input signals and to generate a plurality of output signals, and each of the signal channels has a substantially similar circuit topology. The first proxy channel has a substantially similar circuit topology as the plurality of signal channels, and includes an output that can vary in relation to a common-mode error of the signal channels. The subtraction block is configured to generate a plurality of modified output signals by using the output of the first proxy channel to reduce the common-mode error of the plurality of output signal channels.

Abstract: A system and method for measuring reactive power which uses a pair of quadrate carriers to add a 90 degree phase shift to a voltage path or a current path in a power meter. The quadrate carriers have the same frequency but are offset in phase from each other by 90 degrees.

Abstract: A side-ported MEMS microphone package defines an acoustic path from a side of the package substrate to a microphone die disposed within a chamber defined by the substrate and a lid attached to the substrate. Optionally or alternatively, a circuit board, to which the microphone package is mounted, may define an acoustic path from an edge of the circuit board to a location under the microphone package, adjacent a bottom port on the microphone package. In either case, the acoustic path may be a hollow passage through at least a portion of the substrate or the circuit board. The passage may be defined by holes, channels, notches, etc. defined in each of several layers of a laminated substrate or circuit board, or the passage may be defined by holes drilled, molded or otherwise formed in a solid or laminated substrate or circuit board.

Abstract: A microphone system has a base coupled with first and second microphone apparatuses. The first microphone apparatus is capable of producing a first output signal having a noise component, while the second microphone apparatus is capable of producing a second output signal. The first microphone apparatus may have a first back-side cavity and the second microphone may have a second back-side cavity. The first and second back-side cavities may be fluidly unconnected. The system also has combining logic operatively coupled with the first microphone apparatus and the second microphone apparatus. The combining logic uses the second output signal to remove at least a portion of the noise component from the first output signal.