Sensor interface transceiver

What is claimed is: 1. A control unit, comprising; a sensor interface module configured to output a modulated output voltage to one or more sensors and to receive a modulated sensor current signal from the one or more sensors; an impedance network comprising an impedance element, which is located between the sensor interface module and the one or more sensors; a protocol processor configured to detect one or more properties of the modulated output voltage or the modulated sensor current signal; and an impedance controller configured to selectively adjust a value of the impedance element based upon the one or more properties to improve performance of the control unit. 2. The control unit of claim 1 , wherein the impedance network further comprises at least one of an ohmic component, an inductive component, or a capacitive component. 3. The control unit of claim 1 , wherein the impedance controller comprises: a comparison element configured to generate a control signal if one of the one or more properties violates a performance indicator, wherein the control signal selectively varies the value of the impedance element in a manner that adjusts the one or more properties so that the one or more properties do not violate the performance indicator. 4. The control unit of claim 1 , wherein the sensor interface module comprises: a reference voltage source configured to output a modulated reference signal; a comparator having a first comparator input connected to the reference voltage source, a second comparator input, and a comparator output; a controller comprising a controller input and a controller output, wherein the controller input is coupled to the comparator output and the controller output is coupled to a control terminal of an output driver stage that is configured to provide the modulated output voltage at an output node of the output driver stage; and a first feedback path coupling the output node of the output driver stage to the second comparator input; wherein the comparator is configured to operate the controller to adjust an output of the output driver stage until the modulated output voltage follows the modulated reference signal. 5. The control unit of claim 4 , wherein the controller is selected from the group consisting of a proportional controller, a proportional-integrating controller, or a proportional-integrating differential controller. 6. The control unit of claim 4 , wherein the protocol processor comprises: a receive filter coupled to the controller output and configured to separate the modulated sensor current signal into in-band signal components and out-of-band signal components; and a rectifier configured to receive the out-of-band signal components from the receive filter and to determine a quantity that is proportional to an energy of the out-of-band signal components, which is provided as a property to the impedance controller. 7. The control unit of claim 6 , wherein a value of the impedance element is increased if the quantity is greater than a predetermined value. 8. The control unit of claim 6 , wherein the impedance element comprises an emulated resistor, comprising: a summation element having a first summation input coupled to the reference voltage source, a second summation input, and a summation output coupled to the second comparator input; a second feedback path coupling the comparator output to the second summation input; and a multiplier disposed on the second feedback path, wherein the multiplier is configured to provide a multiplied signal to the second summation input based on a multiplication of a signal on the first feedback path with a virtual resistance value. 9. The control unit of claim 8 , wherein the multiplier is implemented using internal truncation limiting a word length of a product generated by the multiplier. 10. The control unit of claim 8 , wherein the multiplier is implemented using a look-up table for generating a product. 11. The control unit of claim 8 , wherein the second feedback path further comprises at least one filter element, the at least one filter element being implemented as a high-pass filter or a band-pass filter. 12. The control unit of claim 4 , wherein the protocol processor comprises: a wave pattern generator configured to generate a modulated wave pattern that controls the modulated reference signal, and to provide a property comprising a slew rate of the modulated wave pattern to the impedance controller. 13. The control unit of claim 12 , wherein the impedance controller adjusts a value of the impedance element if a slew rate of the modulated output voltage is below or above the slew rate of the modulated wave pattern, thereby changing a time constant of the impedance network to change the slew rate of the modulated output voltage. 14. The control unit of claim 12 , wherein the impedance controller is activated to adjust a value of the impedance element during a voltage modulation phase that transmits data to the one or more sensors and is deactivated to adjust the value of the impedance element during a current modulated phase that receives data from the one or more sensors. 15. The control unit of claim 1 , wherein the impedance element comprises a physical resistive element comprising: a first signal path having a first resistor; a second signal path in parallel with the first signal path and having a second resistor; and a switching element configured to selectively place the first resistor in parallel with the second resistor. 16. A control unit, comprising; a reference voltage source configured to provide a modulated reference signal; a closed control loop configured to drive an output driver stage to provide a modulated output voltage, which tracks the modulated reference signal, to an output node and to receive a modulated sensor current signal from one or more sensors; an impedance network comprising an emulated resistor located between the output driver stage and the one or more sensors; a protocol processor in communication with the closed control loop and the reference voltage source, which is configured to provide a slew rate of the modulated reference signal or out-of-band energy of the modulated sensor current signal to a protocol processor output; and an impedance controller coupled to the protocol processor output and configured to dynamically adjust a value of the emulated resistor if the slew rate or the out-of-band energy violates a performance indicator. 17. The control unit of claim 16 , wherein the protocol processor comprises: a wave pattern generator configured to generate a modulated wave pattern that controls the modulated reference signal, and to provide a slew rate of the modulated wave pattern to the impedance controller. 18. The control unit of claim 17 , wherein the impedance controller adjusts a value of the emulated resistor if a slew rate of the modulated output voltage is below or above the slew rate of the modulated wave pattern, thereby changing a time constant of the impedance network to change the slew rate of the modulated output voltage. 19. The control unit of claim 18 , wherein closed control loop comprises: a comparator having a first comparator input connected to the reference voltage source, a second comparator input, and a comparator output; a controller comprising a controller input and a controller output, wherein the controller input is coupled to the comparator output and the controller output is coupled to a control terminal of an output driver stage that is configured to