Digital synthesizer, radar device and method therefor

The invention claimed is: 1. A digital synthesizer comprising: a ramp generator configured to generate a signal of frequency control words, FCW, that describes a desired frequency modulated continuous wave; a digitally controlled oscillator, DCO, configured to receive the FCW signal and generate a DCO output signal; a feedback loop comprising a time-to-digital converter, TDC, wherein the feedback loop is configured to feed back the DCO output signal; and a phase comparator coupled to the ramp generator and configured to compare a phase of the FCW signal output from the ramp generator with the DCO output signal fed back from the DCO via the feedback loop and output a N-bit oscillator control signal in response thereto; wherein the digital synthesizer is characterized in that: the TDC receives a representation of the DCO output signal and a reference frequency signal to sample the DCO output signal and outputs multiple selectable delays of the DCO output signal; a digital synthesizer circuit sensor is configured to sense an operational condition of the digital synthesizer circuit and select one of the multiple selectable delays output from the TDC in response to the sensed operational condition; and a re-timer circuit is coupled to the digital synthesizer circuit sensor and configured to synchronize the selected delayed DCO output signal with the reference frequency signal. 2. The digital synthesizer of claim 1 , wherein the digital synthesizer circuit sensor is configured to sense at least one operational condition of the digital synthesizer circuit from a group comprising: process, temperature, voltage. 3. The digital synthesizer of claim 1 wherein the digital synthesizer circuit sensor outputs a code based on a measured DCO period by the TDC, indicative of a number of TDC delays to represent a DCO period and thereby one of the multiple selectable delays output from the TDC to be selected. 4. The digital synthesizer of claim 1 , further comprising a DCO period calculation circuit configured to receive a TDC fed back output signal and output a DCO period calculation measurement to the digital synthesizer circuit sensor. 5. The digital synthesizer of claim 4 , wherein the digital synthesizer circuit sensor is configured to use the DCO period calculation measurement to identify a delayed version of the multiple selectable delays of the DCO output signal to be provided to the re-timer circuit. 6. The digital synthesizer of claim 4 , wherein the selected delayed version of the multiple selectable delays includes an indication of whether to: synchronize the DCO output signal, CKV, with the reference frequency signal or synchronize an inverse of the DCO output signal, CKVZ, with the reference frequency signal. 7. The digital synthesizer of claim 1 wherein the TDC is a fractional TDC configured to receive both a frequency divided version of the DCO output signal and the reference frequency signal, and produce therefrom multiple versions of the DCO output signal, each having different delays. 8. The digital synthesizer of claim 7 , further comprising a multiplexer configured to receive the multiple versions of the DCO output signal from the fractional TDC and select one delayed DCO output signal as an output from the multiplexer that is input to the re-timer circuit. 9. The digital synthesizer of claim 7 , wherein the fractional TDC comprises a series of sequential clocked gates, each clocked gate receiving a different delayed DCO output signal and clocked by an inverted or buffered representation of the reference frequency signal in order to produce the multiple versions of the DCO output signal, each having different delays. 10. The digital synthesizer of claim 8 , wherein the digital synthesizer circuit sensor is configured to output a multiplexer signal select signal based on the sensed operational condition of the digital synthesizer circuit such that the multiplexer selects one of the multiple selectable delays for the re-timer circuit to use to synchronize the DCO output signal to the reference frequency. 11. The digital synthesizer of claim 1 wherein the re-timer circuit comprises an integer counter configured to count a number of integer periods of the DCO output signal in each period of the reference frequency clock, in order to generate a delayed DCO output signal resynchronized with a clock edge of the reference frequency clock signal. 12. The digital synthesizer of claim 11 wherein the delayed resynchronized DCO output signal is added in a summing junction to fractional ratio information generated by a period normalisation circuit. 13. The digital synthesizer of claim 12 wherein the summing junction outputs digital signal, which consists of integer and fractional ratio information between the reference frequency clock and a DCO frequency-divided clock signal to the phase comparator. 14. A radar device having a digital synthesizer comprising: a ramp generator configured to generate a signal of frequency control words, FCW, that describes a desired frequency modulated continuous wave; a digitally controlled oscillator, DCO configured to receive the FCW signal and generate a DCO output signal; a feedback loop comprising a time-to-digital converter, TDC, wherein the feedback loop is configured to feed back the DCO output signal; and a phase comparator coupled to the ramp generator and configured to compare a phase of the FCW signal output from the ramp generator with the DCO output signal fed back from the DCO via the feedback loop and output a N-bit oscillator control signal in response thereto; and wherein the digital synthesizer is characterized in that: the TDC receives a representation of the DCO output signal and a reference frequency signal to sample the DCO output signal and outputs multiple selectable delays of the DCO output signal; a digital synthesizer circuit sensor is configured to sense an operational condition of the digital synthesizer circuit and select one of the multiple selectable delays output from the TDC in response to the sensed operational condition; and a re-timer circuit is coupled to the digital synthesizer circuit sensor and configured to synchronize the selected delayed DCO output signal with the reference frequency signal. 15. A method for generating modulation signals in a digital phase locked loop, DPLL, using a re-timer for synchronization that is insensitive to component tolerances, the method comprising: generating a signal of frequency control words, FCW, that describes a desired frequency modulated continuous wave; generating a digitally controlled oscillator, DCO, output signal in response to the FCW signal; feeding back the DCO output signal via a time-to-digital converter, TDC; and comparing a phase of the FCW signal with the DCO output signal and, in response thereto, outputting a N-bit oscillator control signal; wherein the method is characterised by: sampling the DCO output signal using a reference frequency signal to generate multiple selectable delays of the DCO output signal; sensing an operational condition of the digital synthesizer circuit; selecting one of multiple selectable delays output from the TDC in response to the sensed operational condition; and synchronizing the selected delayed DCO output signal with the reference frequency signal.