Non-contact electrical parameter measurement systems

The invention claimed is: 1. A non-contact measurement system, comprising: a housing comprising a front end; a voltage sensor positioned proximate the front end of the housing that, in operation, senses a voltage in an insulated wire without galvanically contacting the insulated wire; a current sensor positioned proximate the front end of the housing that, in operation, senses a current in the insulated wire without galvanically contacting the insulated wire; and at least one processor positioned in the housing, the at least one processor operatively coupled to the voltage sensor and the current sensor, wherein in operation the at least one processor: receives a voltage sensor signal from the voltage sensor obtained by the voltage sensor during a measurement time interval, the voltage sensor signal indicative of the voltage in the insulated wire; receives a current sensor signal from the current sensor obtained by the current sensor during the measurement time interval, the current sensor signal indicative of the current in the insulated wire; and determines at least one alternating current (AC) electrical parameter based at least in part on the received voltage sensor signal and current sensor signal; an alignment feedback sensor operatively coupled to the at least one processor and positioned proximate a front end of a housing of the non-contact measurement system, in operation the alignment feedback sensor generates an alignment feedback sensor signal indicative of a present alignment of the insulated wire with respect to the voltage sensor and the current sensor; and an indicator device operatively coupled to the at least one processor, wherein in operation the at least one processor receives the alignment feedback sensor signal from the alignment feedback sensor, and causes the indicator device to provide an alignment indication to a user of the non-contact measurement system based at least in part on the received alignment feedback sensor signal. 2. The non-contact measurement system of claim 1 wherein the current sensor comprises a magnetic field sensor. 3. The non-contact measurement system of claim 1 wherein the voltage sensor comprises one of a capacitive divider type voltage sensor, a reference signal type voltage sensor, or a multi-capacitor type voltage sensor. 4. The non-contact measurement system of claim 1 wherein the voltage sensor comprises a reference signal type voltage sensor that, in operation, senses a reference signal in the insulated wire without galvanically contacting the insulated wire, and wherein the at least one processor receives the reference signal and determines at least one characteristic of the current flowing through the insulated wire based at least in part on the received reference signal. 5. The non-contact measurement system of claim 1 wherein the at least one AC electrical parameter comprises at least one of power, phase, frequency, harmonics, or energy. 6. The non-contact measurement system of claim 1 wherein in operation the at least one processor determines a plurality of AC electrical parameters based at least in part on the received voltage sensor signal and current sensor signal. 7. The non-contact measurement system of claim 1 , further comprising a display operatively coupled to the at least one processor, in operation the at least one processor causes the display to present the at least one AC electrical parameter. 8. The non-contact measurement system of claim 7 wherein in operation the at least one processor causes the display to present at least one of a waveform or a graph associated with the at least one AC electrical parameter. 9. The non-contact measurement system of claim 1 , further comprising a communications interface operatively coupled to the at least one processor, in operation the at least one processor sends, via the communications interface, data to at least one external device, the data associated with at least one of the voltage sensor signal, the current sensor signal, or the determined at least one AC electrical parameter. 10. The non-contact measurement system of claim 9 wherein the communications interface comprises a wireless communications interface operatively to wirelessly send the data to the at least one external device. 11. The non-contact measurement system of claim 9 , further comprising: at least one external device, comprising: a display; a communications interface that, in operation, receives the data sent by the communications interface of the non-contact measurement system; and at least one processor operatively coupled to the display and the communications interface, in operation the at least one processor: receives, via the communications interface, the data from the non-contact measurement system; and causes the display to present the at least one AC electrical parameter. 12. The non-contact measurement system of claim 1 wherein the indicator device comprises at least one of a visual indicator device or an audible indicator device. 13. The non-contact voltage measurement system of claim 1 wherein the indicator device comprises at least one of a display or a plurality of lights, and in operation the at least one processor causes the indicator device to provide an alignment indication to the user that includes a plurality of colors, each of the plurality of colors corresponding to a different level of alignment of the insulated wire with respect to the voltage sensor and the current sensor. 14. The non-contact measurement system of claim 1 wherein in operation the at least one processor causes the indicator device to provide an indication of measurement accuracy based at least in part on the received alignment feedback sensor signal. 15. The non-contact measurement system of claim 1 wherein in operation the at least one processor causes the indicator device to provide an indication of an energized circuit proximate the insulated wire under test based at least in part on the received alignment feedback sensor signal. 16. A method of operating a non-contact measurement system to determine at least one alternating current (AC) electrical parameter in an insulated wire, the method comprising: sensing, via a voltage sensor positioned in a housing of the non-contact measurement system, a voltage in the insulated wire during a measurement time interval without galvanically contacting the insulated wire; sensing, via a current sensor positioned in the housing of the non-contact measurement system, a current in the insulated wire during the measurement time interval without galvanically contacting the insulated wire; determining, via at least one processor positioned in the housing of the non-contact measurement system, at least one alternating current (AC) electrical parameter based at least in part on the sensed voltage and the sensed current; receiving, from an alignment feedback sensor positioned proximate the front end, an alignment feedback sensor signal indicative of a present alignment of the insulated wire with respect to the voltage sensor and the current sensor; and causing an indicator device positioned on a surface of the housing of the non-contact measurement system to provide an alignment indication to a user of the non-contact measurement system based at least in part on the received alignment feedback sensor signal. 17. The method of claim 16 wherein sensing the voltage comprises sensing the voltage utilizing one of a capacitive divider type voltage sensor, a reference signal type voltage sensor, or a multi-capacitor type voltage sensor, and sensing