Abstract: A universal control unit for driving a brushed or a brushless DC motor, such as the type commonly employed in a vehicle fuel pump or other vehicle application. According to exemplary embodiments, a universal control unit includes a processing device and an output stage, and is connected to either a brushed or a brushless DC motor in a manner that accommodates the two different motor types so that a common or universal controller can be used.

Abstract: A universal control unit for driving a brushed or a brushless DC motor, such as the type commonly employed in a vehicle fuel pump or other vehicle application. According to exemplary embodiments, a universal control unit includes a processing device and an output stage, and is connected to either a brushed or a brushless DC motor in a manner that accommodates the two different motor types so that a common or universal controller can be used.

Abstract: An engine control system includes an engine with an output shaft. A power take-off device interfaces with the output shaft and provides rotational power to an auxiliary device. A user input device includes a first engine speed control that commands an increase in engine speed by a first amount to increase the rotational power to the auxiliary device when a user selects the first engine speed control. A second engine speed control commands an increase in engine speed by a second amount that is greater than the first amount to increase the rotational power to the auxiliary device when the user selects the second engine speed control. The user input device includes a speed cancellation control that commands a reversal of a net increase in the speed of the engine that is commanded via the user input device when the user selects the speed cancellation control.

Abstract: Apparatus are provided for robust power take off (PTO) and/or cruise enable. The apparatus includes a control module for PTO enable having a first input connected to one of a first reference voltage and a second reference voltage, and a second input connected to one of the first reference voltage and the second reference voltage. An inverse reference voltage operator is connected to both of the inputs and configured such that the second input is connected to the second reference voltage when the first input is connected to the first reference voltage and the second input is connected to the first reference voltage when the first input is connected to the second reference voltage. Based on the received voltage at the first and second inputs, the control module enables/disables PTO and/or cruise.

Abstract: An engine control system includes an engine with an output shaft. A power take-off device interfaces with the output shaft and provides rotational power to an auxiliary device. A user input device includes a first engine speed control that commands an increase in engine speed by a first amount to increase the rotational power to the auxiliary device when a user selects the first engine speed control. A second engine speed control commands an increase in engine speed by a second amount that is greater than the first amount to increase the rotational power to the auxiliary device when the user selects the second engine speed control. The user input device includes a speed cancellation control that commands a reversal of a net increase in the speed of the engine that is commanded via the user input device when the user selects the speed cancellation control.

Abstract: Apparatus are provided for PTO related engine control having improved failure modes and communication with PCM or ECM independent of input architecture. The apparatus includes a control module for a vehicle powertrain having an input circuit receiving signals corresponding to a four-bit code, and a processor connected to the input circuit and outputting a control signal corresponding to one of a plurality of four-bit coded engine control states. The engine control states are coded such that potential errors in communication between the control module and powertrain, and their resulting effects on powertrain operation, are minimized. For example, a single bit change during communication does not result in a transition from one engine control state to another engine control state.

Abstract: Systems, methods and devices are described for determining a state of a multi-position actuator such as a four-state switch with a return-to-default position. A circuit for detecting the state of the multi-position actuator suitably includes two or more switches coupled to the actuator and configured to provide input signals as a function of the state of the actuator. At least one of the switches is a ternary (three-state) switch to increase the number of states that can be represented. Control logic receives the input signals from the switches and determines the state of the multi-position actuator as a function of the input signals. This circuit is useful in a number of automotive and other applications, including joysticks, transfer case controls, electric mirror controls, power take-off (PTO) and other devices.

Abstract: Apparatus are provided for PTO related engine control having improved failure modes and communication with PCM or ECM independent of input architecture. The apparatus includes a control module for a vehicle powertrain having an input circuit receiving signals corresponding to a four-bit code, and a processor connected to the input circuit and outputting a control signal corresponding to one of a plurality of four-bit coded engine control states. The engine control states are coded such that potential errors in communication between the control module and powertrain, and their resulting effects on powertrain operation, are minimized. For example, a single bit change during communication does not result in a transition from one engine control state to another engine control state.

Abstract: Apparatus are provided for robust power take off (PTO) and/or cruise enable. The apparatus includes a control module for PTO enable having a first input connected to one of a first reference voltage and a second reference voltage, and a second input connected to one of the first reference voltage and the second reference voltage. An inverse reference voltage operator is connected to both of the inputs and configured such that the second input is connected to the second reference voltage when the first input is connected to the first reference voltage and the second input is connected to the first reference voltage when the first input is connected to the second reference voltage. Based on the received voltage at the first and second inputs, the control module enables/disables PTO and/or cruise.