Abstract: A summing circuit for executing summing of analog data with sign. The summing circuit includes two serially connected inverters INV1 and INV2, each having a feed back line, and selectively inputs data D1 to D8 to one of the first or the second stages, corresponding to positive/negative sign signals S1 to S8.

Abstract: An analog signal selection and summing circuit including a summing amplifier having a current summing input, a plurality of voltage controlled current sources responsive to a plurality of input voltages, a plurality of switching circuits respectively associated with the current sources for controllably switching the outputs of the current sources to the summing input, a plurality of control circuits for respectively controlling the switching circuits.

Abstract: A weighted summing circuit for minimizing bias voltage influence includes capacitive coupling and a closed loop inverter. The weighted summing circuit inputs the output of a capacitive coupling CP.sub.1 to serially connected first and second inverters INV.sub.1 and INV.sub.2, and includes grounded weighted capacitances C.sub.32 and C.sub.11, capacitance C.sub.21 connecting the first and the second inverters INV.sub.1 and INV.sub.2, and a capacitive coupling CP.sub.1 such that the closed loop gains of the first and second inverters INV.sub.1 and INV.sub.2 are substantially equal. The closed loop gains of the first and second inverters INV.sub.1 and INV.sub.2 are balanced.

Abstract: A weighted summing circuit performing a weighted summation using small scale circuitry with a degree of accuracy and that is easily adapted to operate with various kinds of processing systems. Weighted summing circuit includes parallel inductances L.sub.1, L.sub.2 and L.sub.3 having voltages V.sub.1, V.sub.2 and V.sub.3 at a common output V.sub.out.

Abstract: An estimating circuit for application in estimating or deriving the value V.sub.rms.sup.2 or V.sub.peak.sup.2, of a line voltage V.sub.AC provides fast response time and a substantially ripple free value for these signals by the utilization of a controlled harmonic oscillator whose output precisely tracks the input voltage waveform. Two out of phase (by .pi./2) sine wave signals are derived from the input sine wave and these two out of phase signals are squared and summed to derive or estimate the desired square of the sine waveform signal at a fast response time while substantially excluding ripple of the estimated out of phase sine waves. An estimating circuit, described herein, comprises two integrator circuits series connected into a substantially closed loop. The output of the second integrator circuit is fed back to the input of the first integrator circuit. The output of each individual integrator circuit is a voltage sine wave separated in phase from the output of the other integrator by .pi.

Abstract: A threshold circuit that uses capacitors to form a weighted sum of its inputs uses a two stage capacitor structure. The two stages form a compact structure that increases the number of input signals that can be handled and increases the flexibility in assigning the weights to the input signals. Capacitor electrodes for the input signals are arranged in two sets and the electrodes of each set are electrostatically coupled to first and second electrodes. Third and fourth electrodes, which extend from the first and second electrodes respectively, are electrostatically coupled to a unitary structure of fifth and sixth electrodes where their voltages are summed. The fifth and sixth electrodes are conductively connected to the gate of an FET threshold circuit that responds to the weighted and summed input signals.

Abstract: A low power analog absolute differencing circuit includes an integrating amplifier with an input node connected to a common integration line. The common integration line is connected to a set of analog comparison circuits to form an analog vector absolute differencing circuit row. Each of the analog comparison circuits compares a first analog signal to a second analog signal to produce an absolute difference signal. The absolute difference signal from each analog comparison circuit is transmitted in the form of charge drawn from the common integration line. The integrating amplifier provides an integration sum corresponding to the sum of the absolute difference signals. The analog absolute differencing architecture includes a set of analog vector absolute differencing circuit rows arranged to form an analog absolute difference computing array. The analog absolute difference computing array is loaded with a data block input array and a data frame input array.

Abstract: A multiplier circuit includes first and second squaring circuits each having a differential input terminal pair. A first input terminal of the differential input terminal pair of the first squaring circuit is applied with a first input voltage and the second input terminal thereof is applied with a second input voltage opposite in phase to the first input voltage. A first input terminal of the differential input terminal pair of the second squaring circuit is supplied with the second input voltage and the second input terminal thereof is applied with the first input voltage. The first and second squaring circuits each includes two sets of unbalanced differential transistor pairs which are arranged so that their inputs are opposite in phase and their outputs are connected in common. The transistors of each unbalanced differential transistor pair have different emitter sizes.

Abstract: A method for processing electrical signals includes the steps of: storing a plurality of first data signals, each representative of an instantaneous amplitude of a first input signal in a memory; selecting one of the first data signals in response to a second input signal; combining the selected one of the first data signals with a second data signal representative of a subsequent instantaneous amplitude of the first input signal, to produce a difference signal; producing a first output signal in response to the difference signal; and combining the difference signal and the selected first data signal to produce a modified data signal and for replacing the selected one of the first data signals with the modified data signal in the memory. The method can be performed by an equalizer in a circuit for compensating for amplitude variations in a radio frequency signal or by a comb notch filter.

Abstract: Apparatus for generating a phase startable clock signal, comprises an oscillator for providing a continuous sinusoidal input signal, a control signal source for providing a control input signal having a transition between a first state and a second state at a selected time during the signal epoch of the sinusoidal input signal, and a phase splitter, track and holds, multipliers and a summation device for operating on the sinusoidal input signal with the control input signal to produce a sinusoidal output signal commencing with a predetermined phase at a predetermined time relative to the transition.

Abstract: A band gap voltage reference circuit operates between a positive supply voltage and ground. The inputs to a difference amplifier of the band gap reference circuit are biased above the voltage drop of the base-emitter junctions of the band gap reference. The bias voltage is then subtracted from the difference amplifier output by a second difference amplifier. In addition, a bootstrap circuit assures a nonzero output from the first difference amplifier. Other embodiments wherein the band gap reference circuit is more generally a summing circuit are disclosed.

Abstract: Two edge detectors (12, 13) at the input (10.1) and the output (10.2) of a delay line (10) of the edge detector arrangement (11) generate detection signals of identical shape at the detected signal edges of a signal traveling over the delay line. The delay time of the delay line is selected so that the two detection signals partly overlap in time. A subtraction arrangement (16) generates, from the two detection signals, a difference signal that contains, in the overlap region, a zero crossing that can be detected by a zero crossing detector (17). At the time of this zero crossing, the zero crossing detector generates the switching edge of an edge detection signal that controls, for example, a signal switcher (9).

Abstract: A transverse filler for use in a CCD camera eliminates KTC noise even at very fast pixel rates with relatively relaxed constraints on component accuracy and timing control, The circuit includes summation, divider and subtraction circuits which add the plural outputs of a tapped delay line to which a video signal is applied and generate average KTC noise and KTC noise plus signal representations. The output of the circuits is applied to the input of an capacitor and the output of the capacitor is connected to an electronic switch and to a Sample-and-Hold amplifier. The capacitor is operative to subtract the average KTC noise from the average KTC plus Video signal, The circuit is able to run on-board binning and does not have pixel feedthrough problems.