Sensor with interface for functional safety

What is claimed is: 1. A sensor system comprising: a first sensor element configured to provide a first signal component in a first data representation of a sensed quantity; a second sensor element configured to provide a second signal component in a second data representation of the sensed quantity; a signal processing branch configured to operate upon the first signal component and the second signal component; an interface configured to provide a sensor signal, generated based on the first signal component and the second signal component, to a controller, the interface comprising: a high state component configured to receive a first output from a first signal processing path of the first sensor element and control a pull up transistor; and a low state component configured to receive a second output from a second signal processing path coupled to the second sensor element and control a pull down transistor; and the controller configured to detect, based on receiving the sensor signal, a signal processing error. 2. The sensor system of claim 1 , where the controller is configured to detect the signal processing error based on a function of the first signal component and the second signal component. 3. The sensor system of claim 1 , where the first signal component and the second signal component have a proportional relationship to one another and differ according to different representations of the sensed quantity that comprise different trigonometric representations or different inverse representations of the sensed quantity. 4. The sensor system of claim 1 , further comprising: a switching component configured to alternate the first signal component received for processing at a first sensing branch with the second signal component received for processing at a second sensing branch. 5. The sensor system of claim 1 , further comprising: a switching component configured to alternate a polarity of the first signal component at a first sensing branch. 6. The sensor system of claim 1 , further comprising: a synchronizing component configured to determine timeframes associated with the first signal component and the second signal component, the first data representation and the second data representation differing with respect to one another based on different time multiplexing. 7. The sensor system of claim 6 , wherein the synchronizing component is further configured to: generate a comparison of a modulated signal period with an independent oscillator and synchronize the first sensor element and the second sensor element based on the comparison. 8. The sensor system of claim 1 , where a duration of an operational status of the pull up transistor and of the pull down transistor is based on: a range of separation along a signal range of the first signal component and the second signal component, or a time of separation in a time domain of the first signal component and the second signal component. 9. The sensor system of claim 1 , further comprising: a low side controller configured to lock the low state component based on a determination of whether the high state component is actively operating the pull up transistor; and a high side controller configured to lock the high state component based on a determination of whether the low state component is actively operating the pull down transistor. 10. The sensor system of claim 1 , further comprising: a switching component configured to alternate the first signal component in the first data representation of the sensed quantity from the first sensor element with the second signal component in the second data representation of a same sensed quantity within the signal processing branch and another signal processing branch, the first data representation and the second data representation differing based on a separation of a range of a duty cycle. 11. A sensor interface comprising: a first sensor element configured to communicate a measured quantity in a first data representation; a second sensor element configured to communicate the measured quantity in a second data representation; a switching component configured to swap between communicating the first data representation of the measured quantity and the second data representation of the measured quantity; an interface component configured to generate an output signal to an engine controller based on the first data representation and the second data representation, the interface component comprising: a high state component configured to receive a first output from a first signal processing path of the first sensor element and control a pull up transistor; and a low state component configured to receive a second output from a second signal processing path coupled to the second sensor element and control a pull down transistor; and the engine controller configured to detect, based on receiving the output signal, a signal processing error. 12. The sensor interface of claim 11 , where the engine controller is configured to detect the signal processing error based on a function of the first data representation and the second data representation. 13. The sensor interface of claim 11 , where at least one of: the first data representation comprises a first addend of a sum and the second data representation comprises a second addend of the sum, the first data representation comprises a cosine representation and the second data representation comprises a sine representation, or the first data representation is an inverse representation of the second data representation. 14. The sensor interface of claim 11 , further comprising: a synchronizing component configured to generate a comparison of a modulated signal period of the output signal with an independent oscillator, the first data representation and the second data representation differing based on a time of separation in a time domain. 15. The sensor interface of claim 11 , where: the first sensor element comprises a first sensor bridge configured to generate the first data representation of the measured quantity, and the second sensor element comprises a second sensor bridge configured to generate the second data representation, the first data representation and the second data representation having a proportional relationship to one another and differing according to different representations of the measured quantity that comprise different trigonometric representations or different inverse representations of the measured quantity. 16. The sensor interface of claim 11 , where the switching component is further configured to: swap a first signal component in the first data representation and a second signal component in the second data representation at least one of: before the first signal processing path and the second signal processing path, after the first signal processing path and the second signal processing path, or within the interface component. 17. The sensor interface of claim 11 , wherein the switching component is further configured to: swap different polarities of the first sensor element and the second sensor element to communicate the first data representation and the second data representation of the measured quantity based on at least one of: an asymmetrical sequence for identification of at least two time periods corresponding to the polarities, different durations, or a marker inserted into a point in a swapping sequence for swapping the different polarities. 18. A method, comprising: providing, by a system at least parti