Portable spa monitoring and control circuitry

What is claimed is: 1. Voltage sensing circuitry comprising: a first diode connected in series with a current limiting resistance which is in turn connected in series with a Zener diode which is in turn connected in series with an optical coupler LED; wherein an A.C. input voltage to be sensed is coupleable across one terminal of said first diode and one terminal of said optical coupler LED; and wherein the optical coupler LED comprises part of an optical coupler circuit having an output which provides a voltage sense signal comprising a pulse train comprising a plurality of pulses whose respective pulse widths are proportional to the magnitude of the A.C. input voltage. 2. The voltage sensing circuitry of claim 1 further comprising one or more microcontrollers or microprocessors configured to (a) determine the magnitude of the A.C. input voltage from the pulse width of the sensed voltage; (b) determine the frequency of the A.C. input voltage utilizing the period of the pulse train; and (c) determine a zero cross time of the A.C. input voltage waveform. 3. The voltage sensing circuitry of claim 2 wherein the zero cross time is determined by implementing a timer to determine a timer value each time an edge of a pulse of the A.C. input voltage occurs. 4. The voltage sensing circuitry of claim 2 wherein the zero cross time is computed by determining a time of occurrence of the middle of a voltage waveform pulse and then adding or subtracting 25% of that period. 5. The voltage sensing circuitry of claim 2 wherein, to compute the zero cross time, a free running timer is used and the one or more microcontrollers or microprocessors registers the timer value when each edge of a pulse of said pulse train occurs, then computes a center timer value at a midpoint of the pulse, and then adds or subtracts 25% of that timer value to or from the center timer value to establish the timer value for a zero crossing. 6. The voltage sensing circuitry of claim 2 wherein the microcontroller employs an edge sensitive capture input and further employs software to first set the edge sensitive capture input to sense a positive transition of a voltage pulse train, whereafter the next positive signal edge of the pulse train causes the value of a free-running hardware timer to be transferred to a latch at the moment of the said next positive signal edge and also causes an interrupt to vector the microcontroller to a software routine which reads the latch value and re-programs the edge sensitive capture input to sense a negative edge of the pulse train. 7. The voltage sensing circuitry of claim 5 wherein the same process occurs when a negative edge of the voltage pulse train occurs, such that the microcontroller software produces a string of positive and negative edge time values. 8. Voltage sensing circuitry comprising: a first diode connected in series with a current limiting resistance which is in turn connected in series with a Zener diode which is in turn connected in series with an optical coupler LED; wherein an A.C. input voltage to be sensed is coupleable across one terminal of said first diode and one terminal of said optical coupler LED; and wherein the optical coupler LED comprises part of an optical coupler circuit having an output comprising a voltage sense signal. 9. The voltage sensing circuitry of claim 8 wherein the voltage sense signal comprises a pulse train and wherein the voltage sensing circuitry further comprises one or more microcontrollers or microprocessors configured to employ the voltage sense signal to determine the magnitude of the A.C. input voltage from a pulse width of the pulse train. 10. The voltage sensing circuitry of claim 8 wherein the voltage sense signal comprises a pulse train and wherein the voltage sensing circuitry further comprises one or more microcontrollers or microprocessors configured to employ the voltage sense signal to determine the frequency of the A.C. input voltage utilizing a period of the pulse train. 11. The voltage sensing circuitry of claim 8 wherein the voltage sense signal comprises a pulse train and wherein the voltage sensing circuitry further comprises one or more microcontrollers or microprocessors configured to employ the voltage sense signal to determine a zero cross time of the A.C. input voltage waveform. 12. The voltage sensing circuitry of claim 11 wherein the zero cross time is determined by implementing a timer to determine a timer value each time an edge of a pulse of the A.C. input voltage occurs. 13. The voltage sensing circuitry of claim 11 wherein the zero cross time is computed by determining a time of occurrence of the middle of a voltage waveform pulse and then adding or subtracting 25% of that period. 14. The voltage sensing circuitry of claim 11 wherein, to compute the zero cross time, a free running timer is used and the one or more microcontrollers or microprocessors registers the timer value when each edge of a pulse of said pulse train occurs, then computes a center timer value at a midpoint of the pulse, and then adds or subtracts 25% of that timer value to or from the center timer value to establish the timer value for a zero crossing. 15. The voltage sensing circuitry of claim 11 wherein the microcontroller employs an edge sensitive capture input and further employs software to first set the edge sensitive capture input to sense a positive transition of a voltage pulse train, whereafter the next positive signal edge of the pulse train causes the value of a free-running hardware timer to be transferred to a latch at the moment of the said next positive signal edge and also causes an interrupt to vector the microcontroller to a software routine which reads the latch value and re-programs the edge sensitive capture input to sense a negative edge of the pulse train. 16. The voltage sensing circuitry of claim 14 wherein the same process occurs when a negative edge of the voltage pulse train occurs, such that the microcontroller software produces a string of positive and negative edge time values. 17. Voltage sensing circuitry comprising: a first diode connected in series with a current limiting resistance which is in turn connected in series with a Zener diode which is in turn connected in series with an optical coupler LED; wherein the optical coupler LED comprises part of an optical coupler circuit having an output comprising a voltage sense signal; and wherein the first diode is connected to a first line voltage input and the optical coupler LED is connected to a second line voltage input. 18. The voltage sensing circuitry of claim 17 wherein the voltage sense signal comprises a pulse train and wherein the voltage sensing circuitry further comprises one or more microcontrollers or microprocessors configured to employ the voltage sense signal to determine the magnitude of the A.C. input voltage from a pulse width of the pulse train.