Abstract: A system, method and circuit for providing a boost voltage with a transient operation of a vehicular start-stop system are provided. The system includes a duty cycle or current monitor to detect a change in duty cycle or current based on the transient operation; a crank time-out detector to determine whether the change in duty cycle is over a predetermined threshold; and a reset generator to generate a reset of a boost circuit that generates the boost voltage after a predetermined delay.

Abstract: A system, method and circuit for providing a boost voltage with a transient operation of a vehicular start-stop system are provided. The system includes a duty cycle or current monitor to detect a change in duty cycle or current based on the transient operation; a crank time-out detector to determine whether the change in duty cycle is over a predetermined threshold; and a reset generator to generate a reset of a boost circuit that generates the boost voltage after a predetermined delay.

Abstract: A system, method and circuit for providing a boost voltage with a transient operation of a vehicular start-stop system are provided. The system includes a duty cycle or current monitor to detect a change in duty cycle or current based on the transient operation; a crank time-out detector to determine whether the change in duty cycle is over a predetermined threshold; and a reset generator to generate a reset of a boost circuit that generates the boost voltage after a predetermined delay.

Abstract: A limiter circuit includes a voltage rail having an input and an output, the input receiving an applied input voltage, a switching device in electrical communication with the voltage rail to selective control an electric current flowing through the output of the voltage rail, limiter capacitor in electrical communication with the input of the voltage rail and the switching device, wherein the limiter capacitor and the switching device are in parallel electrical communication between the input and an electrical ground, and a first resistor interposed between the limiter capacitor and the electrical ground, wherein an impedance of the resistor and the limiter capacitor define a time constant for the charging the limiter capacitor, and wherein the time constant of the limiter capacitor controls a voltage applied to the switching device and a current flowing through the output of the voltage rail.

Abstract: A regulated voltage supply contains a zener diode controlled by a constant current generator to maintain the zener voltage at a constant level regardless of the swings of the voltage input to the diode. A current amplifier responds to the constant current generator to maintain the output voltage of the regulated voltage supply at the value of the zener voltage regardless of the demands of the load. A low voltage inhibit circuit responds to the magnitude of the input voltage and the magnitude of the voltage on the zener diode to generate a binary voltage signal for inhibiting the operation of a load such as a microcomputer when the voltage regulator is below the zener voltage level and the input is below the desired voltage.

Abstract: A passive processing circuit for processing a ground side switch closure to a CMOS input (20) of an MCU, particularly useful in a D.C. electrical system where ground offsets may occur, such as in an automotive vehicle. Three resistors (R1, R2, R3) are connected between supply and ground potentials of a D.C. power supply voltage (10). The junction of two (R1, R2) connects to an output (16) of a grounded input switch (12). The junction of two (R2, R3) connects to the CMOS input (20). A fourth resistor (R4) connects between the bi-directional input/output (22) of the MCU and the junction of the second and third resistors. The MCU executes an algorithm that selectively allows and disallows the resistor (R4) to coact with the second and third resistors. The circuit provides a cost-efficient solution for extending the range of supply line voltage over which a CMOS input can correctly read a switch closure.

Abstract: In one embodiment of the present invention, an electronic device comprises a circuit board having a first side and a second side and having circuit traces formed only on the first side. The electronic device further includes a voltage regulator providing a regulated voltage via a regulated voltage output terminal and having a regulated voltage return terminal. Additionally, the electronic device includes a microcontroller mounted to the first side of the circuit board and having a plurality of regulated voltage input terminals and corresponding microcontroller voltage return terminals. The electronic device also comprises a bus comprising a first circuit trace coupled to the regulated voltage output terminal and a second circuit trace coupled to the regulated voltage return terminal, the first circuit trace and the second circuit trace running substantially parallel to one another.

Abstract: A detector and battery switch control energy flow from a battery in a vehicle to an electronic module. The vehicle ignition switch controls battery energy flow when the ignition switch is on and the detector and battery switch control battery energy flow when the ignition switch is off. A dimming circuit provides a dimming signal when a demand for energy is made, such as when the headlights are turned on with the ignition switch turned off. The detector senses the dimming signal and operates a battery switch to power up a microprocessor controller from an unpowered state to control operation of the module when the demand for energy is made. There is no sleep mode. A response is made directly to the demand for energy and there is no battery power used until a demand is made for battery energy.

Abstract: Two electronic modules are connected to share and to independently read the sensed value from a single environmental sensor element, by communicating between each other when a particular module is reading the sensor output signal. The sensor output signal is a function of the value of the reference voltage being applied by the reading module and the characteristics of the environment being sensed. A module provides a toggle signal when it completes its reading of the sensor so that the other (non-reading) module will know when it may apply its reference voltage to the sensor and complete its reading of the sensor. The modules alternate the reading of the sensor in order to eliminate the need for a plurality of corresponding sensors.

Abstract: A low cost, less complex microcomputer power supply circuit with temperature stability and low current consumption in which a single voltage regulating element is used to provide the supply voltage, power-on reset (POR) and low voltage inhibitor (LVI) functions to the microcomputer (12). In an exemplary embodiment, the power supply circuit (10) includes a regulating circuit with a zener diode (30) that is conductive when the voltage level of the DC source (14) is above a threshold value and nonconductive when the voltage level of the DC source (14) is below a threshold value. The regulator circuit provides a regulated supply voltage to the microcomputer from the DC source (14). The regulator circuit also provides a regulation signal, whose state depends on the conductivity of the zener diode (30), to a reset circuit. The reset circuit of the power supply circuit is responsive to the regulation signal for providing a reset signal to the microcomputer (12).

Abstract: A short circuit protection system that reacts to a voltage across an electrical load to prevent overdissipation of a semiconductor switch in the event of a short circuit. The system includes a capacitor having a charge state. When the capacitor is charged, the electrical load is turned ON via a transistor. The system automatically latches the electrical load ON until a short circuit occurs or until the capacitor discharges. When a short circuit occurs, the system automatically turns the load OFF.