Abstract: A method for selecting a communication path over which to send a communication load between a first station and a second station in a communication network, in which the communication network has a plurality of possible communication paths between the first and second stations. The method comprises identifying at least one of the possible communication paths between the first and second stations, determining a first path metric for each identified path, the first path metric having a value that may vary as distribution of the load across the network varies and selecting one of the at least one identified paths based on the value of the first path metric for each identified path.

Abstract: An integrated circuit with programmable output drive/program pins includes a plurality of output pads (30) which are each operable to interface with a separate and dedicated output driver (38). The output driver (38) is operable to drive an LED output device (14) in an operating mode. In a program mode, the driver (38) is disabled and a program buffer (40) enabled. At the same time, the LED output device (14) is disabled such that no impedance is presented to the output pad (30) due to operation of the LED output device (14). A programming resistor (18) is disposed between the pad (30) and one of three program reference voltages. A first program state is represented when the resistor (18) is tied to ground, a second program state is represented when the resistor (18) is tied to an open circuit and a third program state is represented when the resistor (18) is tied to a positive voltage.

Abstract: A temperature compensated current source for driving a multi-vibrator (19) includes a voltage generator (10) that outputs a voltage that is proportional to absolute temperature (PTAT) and a resistor (12) for setting the current output by the voltage generator (10). The temperature coefficient of the resistor (12) is chosen such that any variations in the current supplied by the voltage generator (10) are compensated for to result in a current that has substantially no temperature variation. This current is mirrored to a current source (18) for driving the multi-vibrator (19). The voltage across the resistor (12)is a function of temperature, with the current being a function of the value of the resistor (12). The temperature coefficient of the resistor (12) is substantially equal to the temperature coefficient of the voltage generator (10) to yield a temperature coefficient of substantially 0 ppm/.degree.C. for the current.

Abstract: A battery detect circuit (32) is provided that is operable to dispose a sense resistor (50) in series with the battery to determine whether the charge is being provided to the battery or being extracted from the battery. The voltage across the sensor resistor (50) is sensed by a voltage/frequency converter (52). The voltage/frequency converter (52) is a differential structure comprised of two integrator structures (102) and (104) that are operable to utilize a switched capacitor configuration to drive comparators on the output thereof. Each of the integrator structures (102) and (104) has associated therewith passive elements and active elements. The integrators (102) and (104) have associated therewith integration capacitors (147) and (149). Additionally, there are two operational amplifiers (143) and (145) that provide the active components of each of the integrators (102) and (104).

Abstract: An integrated circuit with programmable output drive/program pins includes a plurality of output pads (30) which are each operable to interface with a separate and dedicated output driver (38). The output driver (38) is operable to drive an LED output device (14) in an operating mode. In a program mode, the driver (38) is disabled and a program buffer (40) enabled. At the same time, the LED output device (14) is disabled such that no impedance is presented to the output pad (30) due to operation of the LED output device (14). A programming resistor (18) is disposed between the pad (30) and one of three program reference voltages. A first program state is represented when the resistor (18) is tied to ground, a second program state is represented when the resistor (18) is tied to an open circuit and a third program state is represented when the resistor (18) is tied to a positive voltage.

Abstract: A battery detect circuit (32) is connected to a battery, with the current A battery V:the battery and the current extracted from the battery measured with a sense resistor (50) and convened to charge and discharge voltages with a V/F converter (52). A microcontroller (64) is operable to increment a nominal available charge (NAC) register (180) during a charge operation and to increment a discharge rate counter (DCR) (184) during a discharge operation. The NAC register (180) indicates the available charge, i.e. the charge state of the battery, which value is output to a display (34). The display (34) is controlled to operate in either an absolute full mode or a relative full mode. This is determined by an external programming pin which has first and second programming states associated with the two modes.

Abstract: A battery detect circuit (32) is connected to the battery with the current input to the battery and extracted from the battery measured with a sense resistor (50) and then converted to charge and discharge pulses with a V/F converter (52). A microcontroller (64) is operable to increment a Nominal Available Charge (NAC) register (180) during a charge operation, and to increment a Discharge Count Register (DCR) (184) during a discharge operation. The NAC register (180) indicates the available charge, which value is output to a display (34). The maximum value to which the NAC value can rise is limited by a value stored in the last measured discharge register (182). This value represents the value stored in the DCR (184) whenever the battery is discharged from an apparent full state to a fully discharged state. This results in a qualified transfer to the LMD register (182) such that no knowledge of the actual battery charge is necessary.

Abstract: The low power voltage comparator with hysteresis includes a comparator (10) that is operable to receive the output from a battery (14) on the positive input thereof and the output of a battery (16) on the negative input thereof. An offset circuit (22) is provided in series with the voltage of the battery (14) and the comparator (10), and an offset circuit (24) is provided between the battery (16) and the comparator (10). The offset circuits (22) and (24) are adjustable by a hysteresis control circuit (26) to offset the voltage thereof for the non-selected battery to be higher than that for the selected battery such that the voltage drop across the offset for the non-selected battery is greater than that for the selected battery. When the voltage on the selected battery falls below the offset voltage of the non-selected battery, the hysteresis control then decreases the offset upon selecting the other battery and increases the offset or the battery that is deselected.

Abstract: A battery detect circuit (32) is connected to the battery with the current input to the battery and extracted from the battery measured with a sense resistor (50) and then converted to charge and discharge pulses with a V/F converter (52). A microcontroller (64) is operable to increment a Nominal Available Charge (NAC) register (180) during a charge operation, and to increment a Discharge Count Register (DCR) (184) during a discharge operation. The NAC register (180) indicates the available charge, which value is output to a display (34). The maximum value to which the NAC value can rise is limited by a value stored in the last measured discharge register (182). This value represents the value stored in the DCR (184) whenever the battery is discharged from an apparent full state to a fully discharged state. This results in a qualified transfer to the LMD register (182) such that no knowledge of the actual battery charge is necessary.

Abstract: A power control circuit (10) is operable to select between a backup battery (14) on a terminal (16) and a primary power supply voltage on a terminal (12) to output a voltage to a powered device (20). The two voltages are compared by a comparator (28) that drives a well bias node (44) with transistors (36) and (38). The comparator (28) selects the highest of two voltages on either the battery supply terminal (16) or the power supply terminal (12) to power the node (44), which node (44) is then connected to the wells of switching transistors (40) and (42) which are operable to select the battery terminals (16) in the event of a fail of the power supply on terminal (12). This decision is made with a power failure device (20). In the event that both the primary power supply voltage falls below a predetermined threshold and the battery supply voltage is at a higher level, the battery (14 ) is selected for output on the line (18).

Abstract: A battery detect circuit (32) is connected to the battery with the current input to the battery and extracted from the battery measured with a sense resistor (50) and then converted to charge and discharge pulses with a V/F converter (52). A microcontroller (64) is operable to increment a Nominal Available Charge (NAC) register (180) during a charge operation, and to increment a Discharge Count Register (DCR) (184) during a discharge operation. The NAC register (180) indicates the available charge, which value is output to a display (34). The maximum value to which the NAC value can rise is limited by a value stored in the last measured discharge register (182). This value represents the value stored in the DCR (184) whenever the battery is discharged from an apparent full state to a fully discharged state. This results in a qualified transfer to the LMD register (182) such that no knowledge of the actual battery charge is necessary.

Abstract: A differential comparator is provided for controlling two switches (40) and (42) to switch two supplies (10) and (12), respectively, to a common output node (22). The decision/control circuit (44) outputs two control signals (46) and (48), the logic state thereof being a function of whether supply (10) is higher than supply (12) or supply (12) is higher than supply (10). The operating power for the decision/control circuit (44) is derived from the supplies (10) and (12), and not from the common output node (22), such that when the switches (40) and (42) are closed and no power is being supplied by either of the supplies (10) and (12), the decision/control circuit (44) has sufficient power to make a decision.