Abstract: In an integrated circuit with at least two separate timing circuits, for example both a serializer and a deserializer, a trim value correction factor is developed and applied at the testing of the chip. The correction trim value brings the VCO frequency of the serializer into specifications, but the trim value may also be used to alter the delay between a received clock and data in the deserializer. Since both the serializer and the deserializer were made with the same process, the received clock delay may be corrected by substantially the same correction factor as that applied to the VCO. Illustratively the trim values may be stored on the IC.

Abstract: In an integrated circuit with at least two separate timing circuits, for example both a serializer and a deserializer, a trim value correction factor is developed and applied at the testing of the chip. The correction trim value brings the VCO frequency of the serializer into specifications, but the trim value may also be used to alter the delay between a received clock and data in the deserializer. Since both the serializer and the deserializer were made with the same process, the received clock delay may be corrected by substantially the same correction factor as that applied to the VCO. Illustratively the trim values may be stored on the IC.

Abstract: A clock circuit for outputting serial data without using a PLL is described. The clock is a VCO designed to start at a frequency that is slightly higher than necessary to preserve the data. The frequency of the clock is measured and if the frequency is too high or too low the DC control voltage for the VCO is changed to bring the VCO frequency back to the start frequency. Clock counters, holding registers, comparators, and a D/A form a feed back path around a VCO. In addition, a word boundary generator is used to define individual data words. The word boundary is formed by the absence of a bit clock transition while there is a data bit transition. A high/low threshold may be used where the VCO frequency, as measured, must transcend a threshold before the DC control voltage to the VCO is changed.

Abstract: An overvoltage protection circuit arranged to sense removal of the overvoltage condition. The protection circuit blocks current passing through a pull up transistor of an output circuit to a high-potential supply rail during an overvoltage condition applied at a common bus. The protection circuit includes one protection branch controlled by the potential at the bus and powered by the high-potential supply rail of the output circuit to be protected. The protection circuit also includes a second protection branch controlled by the high-potential supply rail and powered by the potential on the bus. When an overvoltage condition occurs, the second branch is activated and regulates an output from the first protection branch. That output signal controls the control node of the pull up transistor of the output circuit to be protected.

Abstract: A variable base drive output circuit that is operational for low-potential power supplies. The output circuit includes a current regulating branch and a base drive branch. A control transistor is logically coupled to an enable signal and an input signal to be propagated. Activation of that control transistor establishes a current path to the base of a bipolar pulldown transistor that is coupled to output. The current regulating branch includes a resistance device in series with current limiting transistors. The resistance device is coupled to the control node of a base current transistor such that when the load on the output node drops, the current to the base of the pulldown transistor also drops. The result is a savings in Icc current for logic LOW signals at the output node. The variable base drive output circuit is operable for low supply potentials.

Abstract: A power-on reset circuit for a dual-supply system. The reset circuit includes a voltage divider powered by the first power supply and a sub-circuit supplied by the second power supply. The output of the voltage divider is connected to a control node of the first reset sub-circuit that is otherwise powered by the second power supply. A second reset sub-circuit is strictly regulated and powered by the second power supply. The first reset sub-circuit provides for translation of a signal having a potential limited by the potential of the first supply into a signal having a potential associated with that of the second supply. Only when a control signal from the voltage divider reaches a certain potential, and the second power supply reaches a certain potential, is the first reset sub-circuit activated in a manner that results in a circuit output signaling both supplies are at a suitable potential. This is useful for hot insertion applications in dual-supply systems.

Abstract: A buffer circuit for providing dynamic threshold control. The buffer circuit includes a pair of input inverters designed with different skewed threshold potential characteristics. The outputs of the skewed inverters are directed to a logic circuit designed to select either the faster or the slower signal received from the two inverters for transmission to passgate devices coupled to the respective inverters. Only one of the passgate devices is enabled to ensure that only one of the output signals from the two inverters is propagated through the buffer. A latch is preferably connected between the logic circuit and the two passgate devices to maintain the states of the inverters and the logic circuit. The circuit can be designed to define the threshold potential at which switching will occur so as to reduce propagation delay or increase it as desired. It is therefore possible using the circuit to increase transmission rates with minimal affect on signal noise.

Abstract: A fabrication- and temperature-independent power-on reset circuit for providing improved control over live insertion of integrated circuitry. The reset circuit includes a comparator having an output terminal and two input terminals, one positive and one negative. One of the two terminals is coupled to a first threshold turn-on branch and the other terminal is coupled to a second threshold turn-on branch. Both threshold branches are referenced to ground but they supply different initial potentials to the terminals of the comparator. As a result, one terminal acting as the reference terminal holds the circuit output of the present invention at a potential designed to halt circuit power-on regardless of independent enable control pin signals. The other of the two terminals does not trigger switching of the comparator output until after a common supply power rail reaches a desired potential at initial turn-on.

Abstract: A CMOS-based bus-hold circuit having overvoltage tolerance. The bus-hold circuit of the present invention includes, in addition to conventional input and latching inverters, a sense circuit and an arbiter circuit designed in combination to block overvoltage events from powering the latching inverter. The sense circuit includes a comparator designed to compare the potential of a standard high-potential power supply rail to the potential associated with a signal applied to the bus-hold circuit's input node. The higher of those two potentials is used to activate the arbiter circuit that in turn couples the higher of those two signals to a pseudo high-potential power rail. The pseudo high-potential power rail is used to supply power to the latching inverter such that the latching inverter will not be activated during overvoltage conditions, particularly when the circuit is in its high-impedance state. The bus-hold circuit may be similarly designed to establish an undervoltage tolerance as well.

Abstract: An output buffer for reducing the signal noise associated with the switching between logic high and logic low electrical. Signals includes a first clamping circuit linked to the pull-up output transistor of the buffer, and a second clamping circuit linked to the pull-down output transistor of the buffer. The buffer may include both clamping circuits or either the first or second clamping circuit alone, dependent upon signal shaping interests. Each of the clamping circuits includes a selectable delay stage coupled to the buffer's input, a current regulator controlled by the delay stage, and a clamping device that is coupled to the control node of the output transistor. When the current regulator is conducting, the control node of the output transistor is clamped at a potential near its threshold turn-on. As a result, when the clamping circuit is turned off, the output transistor experiences a soft turn-on, thereby reducing signal bounce and the associated noise.