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A system, apparatus, and method for generating backup power in a wireless communications system such as a wireless communications service base station includes a communications interface, a primary power interface, a generator, rectifiers, and a battery circuit. During normal operation, the communic

A system, apparatus, and method for generating backup power in a wireless communications system such as a wireless communications service base station includes a communications interface, a primary power interface, a generator, rectifiers, and a battery circuit. During normal operation, the communications interface is powered from the primary power interface. During a power outage, the communications interface is powered from either the generator or the battery circuit. A battery circuit monitoring circuit detects and/or predicts loose, corroded, intermittent, high resistance, arcing, open, shorted, and/or the like connections.

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1. A power system for a cell site of a wireless communications system, the power system comprising: a battery circuit, including: multiple batteries; multiple jumpers configured to connect two of the batteries in a series configuration, to connect one of the batteries to ground, and to connect anoth

1. A power system for a cell site of a wireless communications system, the power system comprising: a battery circuit, including: multiple batteries; multiple jumpers configured to connect two of the batteries in a series configuration, to connect one of the batteries to ground, and to connect another one of the batteries to a battery circuit output;multiple sense circuits each configured to monitor at least one of the batteries, wherein each sense circuit includes: an opto-isolator circuit coupled across at least one battery and a portion of one jumper, and configured to provide an opto-isolator output to indicate a voltage across the at least one battery and portion of one jumper; and,a high-pass filter configured to pass an alternating current (AC) component of the opto-isolator output to a power controller as a sense circuit output; and,a power controller configured to detect arcing, predict arcing, or both, within the battery circuit, within a ground connection, and within a battery circuit output connection according to integrating a difference in non common-mode components of the AC components of the outputs of each high-pass filter over a time period, and to report detected arcing, predicted arcing, or both, to a remote monitoring facility. 2. The power system of claim 1, wherein each high-pass filter includes an RC filter having a frequency roll off of between approximately four to five kilohertz; wherein each of the multiple batteries is an absorbed glass mat lead-acid battery; wherein the power system is configured to power the wireless communications cell site having a transceiver and associated telecommunications components; wherein the power controller is further configured to detect and/or predict arcing as the multiple batteries transition from discharging to charging or from charging to discharging, to detect a battery circuit error based, at least in part, on a rate of change of the outputs of the high-pass filters, and to detect a battery circuit error based, in part, on a difference between the sense circuit outputs; and, wherein the time period is approximately one minute. 3. The power system of claim 1, wherein the multiple batteries include: a first battery having at least a positive terminal and a negative terminal;a second battery having at least a positive terminal and a negative terminal;a third battery having at least a positive terminal and a negative terminal;a fourth battery having at least a positive terminal and a negative terminal; wherein the multiple jumpers include:a first jumper configured to connect the positive terminal of the first battery to ground; anda second jumper configured to connect the negative terminal of the first battery to the positive terminal of the second battery;a third jumper configured to connect the negative terminal of the second battery to the positive terminal of the third battery;a fourth jumper configured to connect the negative terminal of the third battery to the positive terminal of the fourth battery; and,a fifth jumper configured to connect the negative terminal of the fourth battery to the battery circuit output; and, wherein the multiple sense circuits include:a first sense circuit coupled across at least a portion of the first jumper;a second sense circuit coupled across at least the first battery;a third sense circuit coupled across at least a portion of the second jumper and the second battery;a fourth sense circuit coupled across at least a portion of the third jumper and the third battery; and,a fifth sense circuit coupled across at least a portion of the fourth jumper, the fourth battery, and a portion of the fifth jumper. 4. A power monitoring system operable to monitor a battery circuit having multiple batteries, comprising: multiple sense circuits each configured to monitor voltage across at least one of the batteries and to provide sense circuit outputs to indicate the voltage across the at least one of the batteries; and,a power controller configured to detect arcing, predict arcing, or both, within the battery circuit according to a difference in non common-mode alternating current (AC) components of the sense circuit outputs. 5. The power monitoring system of claim 4, wherein each sense circuit includes: an opto-isolator circuit coupled across at least one battery and configured to provide an opto-isolator output to indicate the voltage across the at least one battery; and,a high-pass filter configured to pass the AC component of the opto-isolator output to the power controller via the sense circuit output. 6. The power monitoring system of claim 4, wherein each sense circuit includes: an opto-isolator circuit coupled across at least one battery and configured to provide an opto-isolator output to indicate the voltage across the at least one battery; and,a high-pass filter configured to pass the AC component of the opto-isolator output to the power controller via the sense circuit output, wherein the power controller is further configured to detect a battery circuit error based, in part, on a rate of change of the sense circuit outputs or a difference between the sense circuit outputs. 7. The power monitoring system of claim 4, wherein each sense circuit includes: an opto-isolator circuit coupled across at least one battery and configured to provide an opto-isolator output to indicate the voltage across the at least one battery; and,a high-pass filter configured to pass the AC component of the opto-isolator output to the power controller via the sense circuit output, wherein each high-pass filter includes a resistor and a capacitor configured together as a high-pass RC filter. 8. The power monitoring system of claim 4, wherein each sense circuit includes: an opto-isolator circuit coupled across at least one battery and a portion of one jumper and configured to provide an opto-isolator output to indicate the voltage across the at least one battery; and,a high-pass filter configured to pass the AC component of the opto-isolator output to the power controller via the sense circuit output, wherein each high-pass filter includes a resistor and a capacitor configured together as a high-pass RC filter having a frequency roll off of between approximately four to five kilohertz. 9. The power monitoring system of claim 4, further comprising other sense circuits configured to monitor a ground connection and an output connection of the battery circuit. 10. The power monitoring system of claim 4, wherein the power controller is configured to detect arcing, predict arcing, or both, as the battery circuit transitions from discharging to charging or from charging to discharging, and to report detected arcing, predicted arcing, or both, to a remote monitoring facility. 11. The power monitoring system of claim 4, wherein the battery circuit is configured to power a wireless communications cell site having a transceiver and associated telecommunications components. 12. The power monitoring system of claim 4, wherein the power controller is further configured to detect arcing, predict arcing, or both, within the battery circuit, within a ground connection of the battery circuit, and within an output connection of the battery circuit according to integrating a difference in non common-mode components of the sense circuit outputs over a time period. 13. The power monitoring system of claim 4, further comprising: the multiple batteries, wherein each of the multiple batteries is an absorbed glass mat lead-acid battery. 14. The power monitoring system of claim 4, further comprising: the battery circuit including: a first battery having at least a positive terminal and a negative terminal;a second battery having at least a positive terminal and a negative terminal; and,a first jumper configured to connect the negative terminal of the first battery to the positive terminal of the second battery such that the first battery and the second battery are configured in a series configuration. 15. The power monitoring system of claim 4, further comprising: the battery circuit including: a first battery having at least a positive terminal and a negative terminal;a second battery having at least a positive terminal and a negative terminal;a third battery having at least a positive terminal and a negative terminal;a fourth battery having at least a positive terminal and a negative terminal;a first jumper configured to connect the positive terminal of the first battery to ground;a second jumper configured to connect the negative terminal of the first battery to the positive terminal of the second battery;a third jumper configured to connect the negative terminal of the second battery to the positive terminal of the third battery;a fourth jumper configured to connect the negative terminal of the third battery to the positive terminal of the fourth battery; and,a fifth jumper configured to connect the negative terminal of the fourth battery to the battery circuit output; and wherein the multiple sense circuits include:a first sense circuit coupled across at least a portion of the first jumper;a second sense circuit coupled across at least the first battery;a third sense circuit coupled across at least a portion of the second jumper and the second battery;a fourth sense circuit coupled across at least a portion of the third jumper and the third battery; and,a fifth sense circuit coupled across at least a portion of the fourth jumper, the fourth battery, and a portion of the fifth jumper. 16. A power monitoring system operable to monitor a battery circuit having multiple batteries, comprising: means for monitoring voltages of at least each of the batteries and to provide indications of the voltages of at least each of the batteries; and,means for detecting and/or predicting arcing within the battery circuit according to differences in non common-mode alternating current (AC) components of the indications, wherein the means for detecting and/or predicting is coupled to the means for monitoring voltages. 17. The power monitoring system of claim 16, further comprising: means for monitoring a ground connection and an output connection of the battery circuit. 18. The power monitoring system of claim 16, wherein the means for detecting and/or predicting further comprises means for detecting and/or predicting arcing within the battery circuit, within a ground connection of the battery circuit, and within an output connection of the battery circuit according to integrating the indications over a time period. 19. A method of monitoring a battery circuit, having multiple batteries, of a cell site of a wireless communications system, comprising: periodically testing the battery circuit by: discharging the battery circuit;monitoring for a discharge error;recharging the battery circuit;monitoring for a recharging error, wherein the monitoring for the discharge error and the monitoring for the recharge error each includes detecting arcing, predicting arcing, or both, within the battery circuit, within a ground connection, and within a battery circuit output connection according to integrating a difference in non common-mode components of the AC components of the voltages across each of the batteries of the battery circuit over a time period. 20. The method of claim 19, further comprising: reporting detecting arcing, predicting arcing, or both, to a remote monitoring facility.