Abstract: One embodiment of a circuit and corresponding method for generating a trigger signal upon the occurrence of either set up or hold time violations in the same waveform acquisition produces a trigger signal referenced to, but displaced in time from, the input clock signal. Transitions (13) in a data signal initiate a window pulse (14') whose duration is equal to the sum of a set up time requirement and a hold time requirement. The window pulse is used as the D input to a flip-flop (20) that is clocked by a version of a clock signal whose active edge has been delayed (28) for an interval that corresponds to the hold time requirement. The output of the flip-flop (20) is a trigger signal that only occurs when a set up or hold time violation has occurred. In another embodiment, triggers generated as the result of a set up time violation are referenced to the clock edge, while triggers that are generated as the result of a hold time violation are referenced to a transition in the data signal.

Abstract: According to the present invention, an R-S latch includes an input stage, a double gate latch stage, and an output stage. The input stage includes a pair of source couplet FETs, a pair of active loads, and a biasing current source. The output of the input stage is coupled to both the latch stage and the output stage, which contains a pair of source follower FETs. The latch stage includes a pair of source coupled double gate FETs. The latch stage provides the switching or latching mechanism which prevents the outputs from changing logic stage until an appropriate set or reset pulse is received. However, one pair of the gates in the latch stage are coupled to an inverted set and reset input. This pair of additional gates enables the Q and Q output to switch symmetrically, thus preventing delay between the Q and Q output.

Abstract: A voltage controlled, triggered oscillator includes a NAND gate and a set of series connected triggerable delay circuits, the output of the NAND gate being fed back to one of its inputs through the delay circuits. A trigger signal is applied to another input of the NAND gate and to triggering inputs of the delay circuits. When the trigger signal is asserted, each delay circuit produces an output signal of state which tracks the state of its input signal but with a predetermined delay so that the NAND gate output oscillates with a frequency determined by the delay times of the delay circuits and the propagation time of the NAND gate. When the trigger signal is deasserted the NAND gate output is terminated and each delay circuit drives its output signal high regardless of the state of its input signal so that the oscillator may be rapidly retriggered.

Abstract: A programmable delay generator is based upon an asynchronous or ripple counter the stages of which change state at definably different times. A full terminal count is decoded including the condition of a lowest order stage which changes state at a unique time which is different from the time at which any other stage changes, for thereby defining an unambiguous delay period. A partial terminal count programmably determines the length of circuit output and the reloading of the ripple counter with a programmable, time delay determining, initial value.

Abstract: A voltage controlled triggered oscillator includes a NAND gate and a set of series connected triggerable delay circuits, the output of the NAND gate being fed back to one of its inputs through the delay circuits. A trigger signal is applied to another input of the NAND gate and to triggering inputs of the delay circuits. When the trigger signal is asserted, each delay circuit produces an output signal of state which tracks the state of its input signal but with a predetermined delay so that the NAND gate output oscillates with a frequency determined by the delay times of the delay circuits and the propagation time of the NAND gate. When the trigger signal is deasserted the NAND gate output is terminated and each delay circuit drives its output signal high regardless of the state of its input signal so that the oscillator may be rapidly retriggered.

Abstract: A device for controlling the output voltage range of a digital-to-analog (D/A) converter of the type wherein the converter output voltage range is proportional to the magnitude of an applied bias current. The device comprises means to sample and store a selected converter output voltage, means to produce a variable current of magnitude proportional to the stored converter output voltage, and a source of constant current. The constant current and the variable current are summed and applied to the converter as the bias current. The converter output voltage range is dependent on the variable portion of the applied bias current which is in turn dependent on the stored, selected converter output voltage.