Abstract: An electronic circuit having a circuit stage, such as a switched capacitor stage or a 1-bit digital-to-analog converter and switched capacitor filter, that is loaded with a load impedance employs current feedforward to substantially cancel effects of the load impedance. A circuit includes a circuit stage and a load impedance following and connected to the circuit stage. A current feedforward circuit is connected to the load impedance, substantially cancelling the load impedance to improve linearity of the digital-to-analog converter or switched capacitor filter.

Abstract: A double-talk detector for an echo canceller includes power estimators (60) and (62) which are utilized to measure the ERLE value in a calculator (64). This ERLE is stored in a register (70) when it is the largest value generated. This register (70) is updated whenever a new and better ERLE occurs. A fraction of the value in register (70) is utilized as an input to a comparator (88), and then compared to the current ERIE value. If the current ERLE differs from the SERLE in register (70) an inhibit signal is generated for blocking the updates of an adaptive filter (40). The value stored in the register (70) is periodically decremented to reduce the value thereof. This decrement operation is performed in response to detection of an utterance from the far-end. A half-Duplex operation is provided with two attentuators (352) and (354) to provide a switching operation and allow only one side access to the communication path.

Abstract: An output driver is provided for operating in a primary power supply environment to drive an output system that can have voltages associated therewith that are higher than the primary power supply level. The driver includes a pull-down N-channel (34) and a pull-up P-channel transistor (44). An output node (40) is driven by the transistor (34) and (44). An N-channel protection device (38) is disposed between node (40) and transistor (34) and an N-channel transistor (48) is disposed between node (40) and transistor (44). Transistor (38) has the gate thereof biased to the primary supply voltage level and the transistor (48) has the gate thereof biased to a voltage slightly above the primary supply voltage level.

Abstract: A very high gain cascode amplifier includes a cascoded differential structure wherein a cascoded N-channel leg comprised of two series connected transistors (56) and (58) are connected between an output node (30) and ground with a corresponding P-channel cascode leg comprised of series connected P-channel transistors (38) and (40) connected between node (30) and V.sub.DD. Transistor (58) is connected to bias voltage, with transistor (56) having a gate thereof connected to a bias circuit (72) which provides gain thereto to increase the gain of a cascoded leg while not introducing any error into the amplifier. The bias circuit (72) has an imbedded structure that sets the gate voltage of transistor (56) to a voltage equal to one threshold voltage plus twice the V.sub.on voltage of transistors (56) and (58).

Abstract: A synchronous serial communication link between a controller and a peripheral is resynchronized by the sending of a series of bits at a first logic level by the controller. The series of bits is long enough to ensure that the peripheral will decode a command word in which all of the bits are at the first logic level. The peripheral, upon decoding such a command word, resets the synchronization circuitry within the peripheral. The controller then sends a single bit of the opposite logic state followed by serial data. The peripheral, upon receipt of this bit of the opposite logic state, releases the synchronization circuitry from its reset condition and begins to decode the serial data in synchronization with the controller.

Abstract: A variable sample rate approximation technique is used for coding and recreating musical signals in a wavetable synthesizer. Many sounds inherently include one large fast transfer of energy followed by vibrations that dampen over time so that the bandwidth requirement of a musical sound is reduced with passing time. Using the variable sample rate approximation technique, musical sounds are classified into two categories, sustaining sounds and percussive sounds. A sustaining instrument creates a noisy stimulus then sustains the sound created by the noisy stimulus. A percussive instrument is also a noisy source and generates a sound signal having high frequencies that decay rapidly while sustaining instruments sustain at all frequencies nearly equally. The sustaining and percussive instruments have substantially different waveform characteristics but present similar conditions with respect to memory reduction.

Abstract: The present invention relates to a signal driver circuit for driving a liquid crystal display panel. The signal driver circuit provides level shifting within the circuit to lower the power consumption of a liquid crystal display module while still providing a wide analog voltage range to the liquid crystal display elements. The decoding circuits utilize a strand of abutting decode input transistors which are connected in series. Further to reduce the physical size of the decoding circuits, multiple decode circuits may share circuitry that decodes the most significant bits of a data word. A cell layout is utilized such that the most significant bits data are bused into the cell through metal lines and the least significant bits are bused in polysilicon that also operates as the gate of the decode input transistors. Moreover, the decode cell input transistors may all be of the same conductivity type.

Abstract: The present invention relates to a signal driver circuit for driving a liquid crystal display panel. The signal driver circuit provides level shifting within the circuit to lower the power consumption of a liquid crystal display module while still providing a wide analog voltage range to the liquid crystal display elements. The decoding circuits utilize a strand of abutting decode input transistors which are connected in series. Further to reduce the physical size of the decoding circuits, multiple decode circuits may share circuitry that decodes the most significant bits of a data word. A cell layout is utilized such that the most significant bits data are bused into the cell through metal lines and the least significant bits are bused in polysilicon that also operates as the gate of the decode input transistors. Moreover, the decode cell input transistors may all be of the same conductivity type.

Abstract: The present invention relates to a signal driver circuit for driving a liquid crystal display panel. The signal driver circuit provides level shifting within the circuit to lower the power consumption of a liquid crystal display module while still providing a wide analog voltage range to the liquid crystal display elements. The decoding circuits utilize a strand of abutting decode input transistors which are connected in series. Further to reduce the physical size of the decoding circuits, multiple decode circuits may share circuitry that decodes the most significant bits of a data word. A cell layout is utilized such that the most significant bits data are bused into the cell through metal lines and the least significant bits are bused in polysilicon that also operates as the gate of the decode input transistors. Moreover, the decode cell input transistors may all be of the same conductivity type.

Abstract: The present invention relates to a tone signal generator. The tone signal generator includes first tone signal generation means for producing a dual-tone, multi-frequency ("DTMF") audio signal; second tone signal means for producing a plurality of non-DTMF audio signals; storage means for storing data that represents at least one channel of an output audio tone signal; and selection means for selectively loading the DTMF signal into the storage means and for selectively accumulating the non-DTMF signals into the storage means so as to generate the output tone signal.

Abstract: A method for changing the frequency of a low-pass Finite Impulse Response (FIR) filter with a fixed frequency clock utilizes a decimation-by-coefficient technique. The decimation-by-coefficient method utilizes a single set of coefficients that are stored in a coefficient Read Only Memory (ROM) (64). Data is input to an elastic buffer (60) with multiplications performed by a multiplication circuit (62). To realize a low frequency filter, all coefficients are utilized in the multiplication operations with sequential multiplies. These are accumulated in register (70), this providing a high precision filter. To increase frequency by a factor of two--to decimate the coefficients by a factor of two, it is only necessary to utilize every other coefficient, such that only a single fixed clock (78) is required.

Abstract: A variable gain echo suppressor is provided that utilizes two variable attenuators (410) and (412) that are disposed in the receive and transmit paths, respectively, of a communication system. An echo suppressor (414) receives the input from the far end and transmits the output from the near end and controls the two attenuators to set a variable gain therein. The echo suppressor utilizes a normalized power level which is normalized with respect to the background noise at the respective end and then takes the ratio of this normalized power and the normalized power at the opposite end to define an associated power ratio. This power ratio value is utilized to determine the attenuation for the associated end. When the power ratio is high, this indicates that a stronger signal is being received from that end and a small amount of attenuation is associated in the transmit path from that end. When they aye equal, this will result in both systems having approximately the same attenuation, a mid-level attenuation.

Abstract: A frequency modulation (FM) tone signal generator for generating a FM tone signal is disclosed. The tone signal generator includes a waveform generator having a plurality of wave tables, a selector and an enveloper. The waveform generator furnishes a waveform signal in response to a phase angle address signal. Each wave table stores a different waveform. The selector selects one of the wave tables in response to a plurality of selection signals such that the selected wave table largely provides the waveform signal upon being addressed largely by the phase angle address signal. Selection of the selected wave table varies with each selection signal. The enveloper impresses an envelope signal on the waveform signal. The envelope signal is used as a carrier or modulator for generating the FM tone signal.

Abstract: An analog-to-digital converter is comprised of an analog delta-sigma modulator (10) and a digital processing section (14). The digital processing section (14) is comprised of a plurality of digital processing sections fabricated on a monolithic device. A high precision FIR filter (20) is provided for providing a high resolution output on a bus (22). Additionally, a low group delay FIR filter (30) is provided to filter the data and provide an output with a much lower delay than that of the FIR filter (20). The output of filter (20) can either be processed through a high-pass filter (40) and/or through a noise shaping psycho-acoustic filter (36) to provide select outputs. These outputs are all input to the serial interface device (52), which is operable to select one of the outputs, that of the filter (30), that of the filter (20), or that of the output of the noise shaping filter (36) or that of the filter (40) for conversion to a serial data stream.

Abstract: The detrimental nonlinear charging currents from an analog input signal through an anti-aliasing filter into a sampling circuit can be minimized by using primary and secondary inputs to the sampling circuit. The secondary input is turned on before the primary input and the charge required to charge the parasitic capacitance inside the sampling circuit and to replenish the channeling charge lost in the previous cycle is supplied primarily through the secondary input. Immediately after the secondary input is turned off the primary input is connected to the sampling node, and only the charge required to fine tune the signal into the sampling capacitor is drawn through the primary input. Therefore, most of the non-linear charge injection is passed through the secondary input, and the signal passed through the primary input is used to fine tune the voltage levels inside the sampling circuit during the actual sampling operation.

Abstract: A frequency modulation (FM) tone signal generator for generating a FM tone signal is disclosed. The tone signal generator includes a waveform generator having a plurality of wave tables, a selector and an enveloper. The waveform generator furnishes a waveform signal in response to a phase angle address signal. Each wave table stores a different waveform. The selector selects one of the wave tables in response to a plurality of selection signals such that the selected wave table largely provides the waveform signal upon being addressed largely by the phase angle address signal. Selection of the selected wave table varies with each selection signal. The enveloper impresses an envelope signal on the waveform signal. The envelope signal is used as a carrier or modulator for generating the FM tone signal.

Abstract: An algorithmic converter system includes an algorithmic converter having a loop gain substantially less than two for converting an analog input signal to a redundant digital code; and a digital computation unit for converting the redundant digital code to a digital output signal by computing a polynomial of a radix, said radix being substantially equal to the loop gain, wherein the redundant digital code specifies coefficients of the polynomial. The redundancy extends the analog input conversion range with respect to the voltage reference of the algorithmic converter. Moreover, if the algorithmic converter has a maximum offset of V.sub.offmax, a reference voltage of V.sub.ref, and a loop gain less than 2/(1+V.sub.offmax /V.sub.ref), then loop offset will not cause differential nonlinearities. Nonlinearity is further reduced by digitally compensating for variations in the loop gain.

Abstract: An amplifier having an inverting and a non-inverting input and at least one output is compensated by dynamically varying the transconductance of a gain stage in accordance with the gain of the output stage of the amplifier. The amplifier comprises a gain section having at least one output, where a gm of the gain section varies with a transconductance control signal. The amplifier further comprises an output stage comprising a output drive device controlled by an output of the gain section. A bias control circuit is coupled to drive the transconductance control input of the gain section, the bias control circuit increasing a differential mode transconductance of the first gain stage when the active pullup or pulldown output drive device has low gain.

Abstract: A double-talk detector for an echo canceller includes power estimators (60) and (62) which are utilized to measure the ERLE value in a calculator (64). This ERLE value is stored in a register (70) when it is the largest value generated. This register (70) is updated whenever a new and better ERLE occurs. A fraction of the value in register (70) is utilized as an input to a comparator (88), and then compared to the current ERLE value. If the current ERLE differs from the SERLE in register (70) an inhibit signal is generated for blocking the updates of an adaptive filter (40). The value stored in the register (70) is periodically decremented to reduce the value thereof. This decrement operation is performed in response to detection of an utterance from the far-end.

Abstract: A differential input stage for a data conversion device includes two sections, one section for operating during a high stress portion of a charge transfer operation and one portion for operating during the remainder of the charge transfer operation. The first portion is comprised of two differential transistors (84) and (86) having the sources and bodies thereof connected to a source coupled node and connected through a switch (94) to a current source (92). The drains of transistors (84) and (86) are connected through switches (110) and (112), respectively, to output terminals. During the second half of the charge transfer operation, differential transistors (78) and (88), having the sources and bodies thereof connected to a source coupled node and connected to the current source (92) through a switch (90), are rendered operable with the drains thereof connected through switches (96) and (104), respectively, to the output terminals. Only one of the differential pairs is operable at any one time.