Method and apparatus for generating a frequency estimation signal

The invention claimed is: 1. A frequency estimation signal generator component arranged to receive an input frequency signal and to generate therefrom a frequency estimation signal, the frequency estimation signal generator component comprising: a counter component arranged to receive an oscillating signal derived by dividing the input frequency signal with a divider component and to output a plurality of physically separate digital control signals, wherein the counter component is arranged to output a temporal sequence of control signal patterns for each of the physically separate digital control signals and is controllable by the received oscillating signal to sequentially step through the control signal patterns; and a continuous waveform generator component arranged to receive the plurality of physically separate digital control signals output by the counter component and a weighted analogue signal for each of the received physically separate digital control signals, and to output a continuous waveform sinusoidal signal comprising a sum of the weighted analogue signals for which the corresponding physically separate digital control signals comprise an asserted logical state; wherein the frequency conversion component is arranged to derive the frequency estimation signal from the continuous waveform sinusoidal signal output by the continuous waveform generator component. 2. The frequency estimation signal generator component of claim 1 , wherein the counter component is arranged to sequentially step through the control signal patterns upon every n cycle(s) of the received oscillating signal, where n≥1. 3. The frequency estimation signal generator component of claim 1 , wherein the counter component is arranged to output a set of M digital control signals made up of a first subset of M/2 down control signals, and a second subset of M/2 up control signals. 4. The frequency estimation signal generator component of claim 3 , wherein the counter component is arranged to generate the sequence of control signal patterns comprising: a down asserting phase during which the subset of down control signals are sequentially transitioned from un-asserted states to asserted states; a down de-asserting phase during which the subset of down control signals are sequentially transitioned from asserted states to un-asserted states; an up asserting phase during which the subset of up control signals are sequentially transitioned from un-asserted states to asserted states; and an up de-asserting phase during which the subset of up control signals are sequentially transitioned from asserted states to un-asserted states. 5. The frequency estimation signal generator component of claim 3 , wherein the continuous waveform generator component comprises: a set of M switch drivers, each switch driver arranged to receive one of the control signals output by the counter component and to output a driver signal derived from the received control signal; and a set of switching components arranged to receive the driver signals output by the switch drivers and the weighted analogue signals and to collectively generate the continuous waveform signal comprising a sum of the weighted analogue signals for which the corresponding driver signals comprise the asserted logical state. 6. The frequency estimation signal generator component of claim 5 , wherein each switching component comprises a tri-state operation and is arranged to receive a pair of driver signals and a pair of weighted analogue signals, and to steer the weighted analogue signals to an up output, a down output or to both outputs, depending on the received driver signals. 7. The frequency estimation signal generator component of claim 6 , wherein each switching component is arranged to receive a pair of driver signals derived from complementary up and down control signals and a pair of equally weighted analogue signals. 8. The frequency estimation signal generator component of claim 5 , wherein: the analogue signals at the up outputs of the set of switching components are combined to generate an up voltage signal; the analogue signals at the down outputs of the set of switching components are combined to generate a down voltage signal; and the continuous waveform signal is generated based on the resulting up and down voltage signals. 9. The frequency estimation signal generator component of claim 1 , wherein the sequence of control signal patterns generated by the counter component and the weighted analogue signals are arranged such that the continuous waveform signal output by the continuous waveform generator comprises a sinusoidal profile. 10. The frequency estimation signal generator component of claim 1 , wherein the weighted analogue signals comprise weighted current signals, and the continuous waveform signal output by the continuous waveform generator comprises a continuous summed current signal applied to a load to convert the continuous summed current signal into a continuous waveform voltage signal. 11. The frequency estimation signal generator component of claim 1 , wherein the frequency estimation signal generator component further comprises a divider component arranged to receive the input frequency signal and to perform frequency division of the input frequency signal to generate the oscillating signal received by the counter component. 12. The frequency estimation signal generator component of claim 1 , wherein the frequency estimation signal generator component further comprises a low-order filter arranged to perform low-order filtering of the frequency estimation signal. 13. A frequency monitor circuit for performing run-time frequency monitoring of an input signal, the frequency monitor circuit comprising at least one frequency estimation signal generator component according to claim 1 . 14. The frequency monitor of claim 13 , wherein the frequency monitor circuit is arranged to perform run-time frequency monitoring of an oscillator signal for a Frequency-Modulated Continuous Wave, FMCW, automotive radar system. 15. A method of generating a frequency estimation signal for performing run-time frequency monitoring of an input frequency signal, the method comprising: receiving the input frequency signal; sequentially outputting a temporal sequence of control signal patterns over a plurality of physically separate digital control signals under the control of an oscillating signal derived by dividing the received input frequency signal; receiving a weighted analogue signal for each of the physically separate digital control signals; outputting a continuous waveform sinusoidal signal comprising a sum of the weighted analogue signals for which the corresponding physically separate digital control signals comprise an asserted logical state; and deriving the frequency estimation signal from the continuous waveform sinusoidal signal.