Measuring capacitance of a capacitive sensor with a microcontroller having an analog output for driving a guard ring

What is claimed is: 1. A microcontroller comprising: a digital processor with memory; a plurality of external input/output nodes that can be programmed to function as analog nodes, a multiplexer controlled by the digital processor for selecting one of said analog nodes and coupling the analog node to an analog bus; an analog-to-digital converter (ADC) coupled with the analog bus for converting an analog voltage on the analog bus to a digital representation thereof and having a digital output coupled to the digital processor for conveying the digital representation, and a further external node operable to be connected by means of a programmable switch controlled by the digital processor to the analog bus independent from said multiplexer and in addition to one of the selected external input/output nodes. 2. A microcontroller according to claim 1 , further comprising: at least one analog output driver; a sample and hold capacitor associated with the ADC; a first analog node coupled to a first analog bus in the microcontroller; a second analog node coupled to a second analog bus in the microcontroller, the second analog bus is also coupled to an input of the at least one analog output driver; the first analog bus is switchably coupled to a power supply common, a power supply voltage, the sample and hold capacitor, or the second analog bus; the second analog bus is switchably coupled to the power supply common, the power supply voltage, or the first analog bus; the sample and hold capacitor is switchably coupled to either the first analog bus or an input of the ADC; and at least one third analog output node of the microcontroller is coupled to a respective one of the at least one analog output driver. 3. The microcontroller according to claim 2 , wherein the second analog node is adapted for coupling to a capacitive sensor. 4. The microcontroller according to claim 2 , wherein the at least one third analog output node is adapted for coupling to a guard ring associated with the capacitive sensor, wherein a voltage on the guard ring is substantially the same voltage as on the capacitive sensor. 5. The microcontroller according to claim 2 , wherein the first analog node is adapted for coupling to an external capacitor. 6. The microcontroller according to claim 2 , further comprising a plurality of switches, wherein: a first one of the plurality of switches couples the first and second analog buses together when closed, a second one of the plurality of switches couples the first analog bus to a power supply common when closed, a third one of the plurality of switches couples the second analog bus to a power supply voltage when closed, a fourth one of the plurality of switches couples the first analog bus to the power supply voltage when closed, and a fifth one of the plurality of switches couples the second analog bus to the power supply common when closed. 7. The microcontroller according to claim 6 , wherein the digital processor controls the plurality of switches. 8. The microcontroller according to claim 6 , wherein the plurality of switches are a plurality of field effect transistor (FET) switches. 9. The microcontroller according to claim 1 , further comprising at least one internal capacitor switchably coupled to the first analog bus. 10. The microcontroller according to claim 1 , further comprising: a precision timer coupled to the digital processor; a plurality of switches; a first node coupled to the plurality of switches, the first node is also adapted for coupling to an external capacitive sensor; a sample and hold circuit having a control input coupled to the precision timer, an analog input coupled to the first node and an analog output coupled to an input of the ADC; a constant current source coupled to the plurality of switches; wherein the plurality of switches are controlled by the precision timer for coupling the first node to either a power supply common or the constant current source; a second node; and an analog driver having an analog input coupled to the first node and an analog output coupled to the second node, whereby a voltage on the second node is substantially the same as a voltage on the first node; wherein the second node is adapted for coupling to an external guard ring associated with the external capacitive sensor; wherein the first node is coupled to the power supply common through the plurality of switches until a start of a precision time period determined by the precision timer then the first node is coupled to the constant current source, whereby the external capacitive sensor is charged by the constant current source until a stop of the precision time period determined by the precision timer; after the stop of the precision timer occurs a sample of a voltage charge on the external capacitive sensor is taken by and stored in the sample and hold circuit; the sampled and stored voltage charge is converted by the ADC to a digital representation thereof; and the digital processor reads the digital representation from the ADC and determines a capacitance value of the external capacitive sensor from the precision time period and the digital representation of the voltage charge. 11. The microcontroller according to claim 10 , further comprising: a constant current sink coupled to the plurality of switches; wherein the first node is coupled to a power supply voltage through the plurality of switches until a start of another precision time period determined by the precision timer then the first node is coupled to the constant current sink, whereby the external capacitive sensor is discharged by the constant current sink until another stop of the precision time period determined by the precision timer; after the another stop of the precision timer occurs a sample of another voltage charge on the external capacitive sensor is taken by and stored in the sample and hold circuit; the sampled and stored another voltage charge is converted by the ADC to another digital representation thereof; and the digital processor reads the another digital representation from the ADC and determines a capacitance value of the external capacitive sensor from the another precision time period and the another digital representation of the another voltage charge. 12. The microcontroller according to claim 1 , further comprising: a variable frequency oscillator; a frequency measurement circuit having an output coupled to the digital processor and an input coupled to the variable frequency oscillator; a first node coupled to the variable frequency oscillator, the first node is also adapted for coupling to an external capacitive sensor; a second node adapted for coupling to an external guard ring associated with the external capacitive sensor; and an analog driver having an analog input coupled to the first node and an analog output coupled to the second node, whereby a voltage on the second node is substantially the same as a voltage on the first node; wherein the external capacitive sensor is part of a frequency determining circuit of the variable frequency oscillator, whereby a frequency of the variable frequency oscillator changes when a capacitance value of the external capacitive sensor changes; wherein the frequency measurement circuit measures and converts the frequency of the variable frequency oscillator into a digital representation thereof; and wherein the digital processor reads the digital representation of the frequency and determines a capacitance value of the external capacitive sensor. 13. A capacitive sensor system, said system comprising: a capacitive sensor; a guard ring associ