Electrical system with arc fault detection

What is claimed is: 1. An electrical system, comprising: a first electrical component; a second electrical component; a conductor electrically coupling the first electrical component with the second electrical component; a sensor constructed to sense an AC power flow in the conductor and output an AC signal proportional to the AC power flow; a band-pass filter in electrical communication with the sensor and constructed to receive and filter the AC signal, wherein the band-pass filter is constructed to pass AC signals at frequencies associated with arcing and to not pass AC signals at other frequencies, and to generate an AC voltage proportional to the AC signals that are passed by the band-pass filter; and a controller in electrical communication with the band-pass filter, the controller being operative to receive and sample the AC voltage from the band-pass filter, and the controller being configured to sum sequential AC voltage values received from the band-pass filter over a sample time period; and to determine whether an arc fault has occurred based on the summed AC voltage values, wherein the controller is configured to generate a weighted counter, wherein the weighted counter is constructed to increment a count when the summed AC voltage values exceed a threshold value, and to decrement the count when the summed AC voltage values do not exceed the threshold value; and wherein the controller is further configured to set an arc fault flag in response to the count exceeding a threshold count. 2. The electrical system of claim 1 , wherein the controller is configured to generate absolute values of the AC voltage output; and wherein the summed AC voltage values are summed absolute AC voltage values. 3. The electrical system of claim 1 , wherein the band-pass filter is an analog band-pass filter. 4. The electrical system of claim 3 , wherein the band-pass filter is a three Sallen-Key band-pass filter. 5. The electrical system of claim 1 , wherein the band-pass filter is tuned to yield a pass band having multiple peaks. 6. The electrical system of claim 1 , wherein the controller is configured to perform a statistical test on the summed AC voltage values and to track a deviation from a non-faulted condition. 7. The electrical system of claim 1 , wherein the controller is configured to determine whether the arc fault is a persistent fault. 8. The electrical system of claim 1 , further comprising a circuit interrupter operative to open-circuit the conductor in response to the controller determining that the arc fault has occurred. 9. An electrical system, comprising: a first electrical component; a second electrical component; a conductor electrically coupling the first electrical component with the second electrical component; a sensor constructed to sense an AC power flow in the conductor and output an AC signal proportional to the AC power flow; a band-pass filter in electrical communication with the sensor and constructed to receive and filter the AC signal, wherein the band-pass filter is constructed to pass AC signals at frequencies associated with arcing and to not pass AC signals at other frequencies, and to generate an AC voltage proportional to the AC signals that are passed by the band-pass filter; and a controller in electrical communication with the band-pass filter, the controller being operative to receive and sample the AC voltage from the band-pass filter, and the controller being configured to sum sequential AC voltage values received from the band-pass filter over a sample time period; and to determine whether an arc fault has occurred based on the summed AC voltage values, wherein the controller is configured to set an initial sample time period; compare the summed AC voltage values during the initial sample time period to a first threshold; and set an increased sample time period in response to the summed AC voltage values exceeding the first threshold. 10. The electrical system of claim 9 , wherein the controller is configured to, in response to the summed AC voltage values exceeding the first threshold, compare the summed AC voltage values during the increased sample time period to a second threshold higher than the first threshold; and to set an arc fault flag in response to the summed AC voltage values during the increased sample time period exceeding the second threshold. 11. A DC photovoltaic system, comprising: a solar panel; a conductor; an inverter in electrical communication with the solar panel via the conductor; a current transformer constructed to sense an AC current in the conductor and output an AC signal proportional to the AC current; a band-pass filter in electrical communication with the current transformer and constructed to receive and filter the AC signal, wherein the band-pass filter is constructed to pass AC signals at frequencies associated with arcing and to not pass AC signals at other frequencies, and to generate an AC voltage proportional to the AC signals that are passed by the band-pass filter; and a controller in electrical communication with the band-pass filter, the controller being operative to receive and sample the AC voltage from the band-pass filter, and the controller being configured to sum sequential AC voltage values received from the band-pass filter over a sample time period; and to determine whether an arc fault has occurred based solely on the summed AC voltage values, wherein the controller is configured to generate a weighted counter, wherein the weighted counter is constructed to increment a count when the summed AC voltage values exceed a threshold value, and to decrement the count when the summed AC voltage values do not exceed the threshold value; and wherein the controller is further configured to set an arc fault flag in response to the count exceeding a threshold count. 12. The DC Photovoltaic system of claim 11 , wherein the controller is configured to repeat the summing of the sequential AC voltage values received from the band-pass filter over a plurality of sample time periods. 13. The DC photovoltaic system of claim 11 , wherein the controller is configured to perform a statistical test on the summed AC voltage values and to track a deviation from a non-faulted condition. 14. The DC photovoltaic system of claim 11 , wherein the controller is configured to determine whether the arc fault is a persistent fault. 15. The DC photovoltaic system of claim 11 , wherein the band-pass filter is a three Sallen-Key band-pass filter; and wherein the band-pass filter is tuned to yield a pass band having multiple peaks. 16. A DC photovoltaic system, comprising: a solar panel; a conductor; an inverter in electrical communication with the solar panel via the conductor; a current transformer constructed to sense an AC current in the conductor and output an AC signal proportional to the AC current; a band-pass filter in electrical communication with the current transformer and constructed to receive and filter the AC signal, wherein the band-pass filter is constructed to pass AC signals at frequencies associated with arcing and to not pass AC signals at other frequencies, and to generate an AC voltage proportional to the AC signals that are passed by the band-pass filter; and a controller in electrical communication with the band-pass filter, the controller being operative to receive and sample the AC voltage from the band-pass filter, and the controller being configured to sum sequential AC voltage values received from the band-pass filter over a sample time period; and to determine whether an arc fault has occurred bas