Digital synthesizer, communication unit and method therefor

The invention claimed is: 1. A digital synthesizer comprising: a digitally controlled oscillator, DCO; a feedback loop; a ramp generator configured to generate a signal of frequency control words, FCW, that describes a desired frequency modulated continuous wave; and a phase comparator configured to compare a phase of the FCW output from the ramp generator and a signal fed back from the DCO via the feedback loop and output a N-bit oscillator control signal; wherein the digital synthesizer comprises a gain circuit coupled to a multiplier located between the ramp generator and the DCO and configured to apply a frequency-dependent gain signal to the N-bit oscillator control signal to maintain an open loop gain of the all-digital phase locked loop, ADPLL, and a PLL loop bandwidth that is substantially constant across a frequency modulation bandwidth, the open loop gain variations are controlled according to predefined DCO gain variations determined across a range of DCO frequencies, and the predefined DCO gain variations determined across a range of DCO frequencies are obtained through measurements of DCO gains. 2. The digital synthesizer of claim 1 , wherein the frequency-dependent gain is represented by K DCO and the gain circuit applies a reference frequency/Kdco_est gain to the N-bit oscillator control signal to compensate for a DCO gain variation. 3. The digital synthesizer of claim 1 , wherein the gain circuit applies the frequency-dependent gain dynamically during a generation of frequency modulated continuous wave radar ramp-up signals. 4. The digital synthesizer of claim 1 , wherein the multiplier is configured to multiply the N-bit oscillator control signal with a concurrently generated gain signal that is representative of a curve of a reference frequency divided by the frequency-dependent gain represented by K DCO . 5. The digital synthesizer of claim 4 , wherein the curve is a linear curve or polynomial curve. 6. The digital synthesizer of claim 1 , wherein the predefined DCO gain variations determined across a range of DCO frequencies are stored in a look-up table coupled to the digital synthesizer. 7. The digital synthesizer of claim 1 , wherein the predefined DCO gain variations determined across a range of DCO frequencies are obtained through measurements of DCO gains and applied using an odd order polynomial that is located in, or coupled to, the ramp generator. 8. The digital synthesizer of claim 1 , wherein the digital multiplier is located anywhere between an output of the phase comparator and an input of the DCO. 9. The digital synthesizer of claim 1 , further comprising a loop filter located between the phase comparator and multiplier and configured to filter the N-bit oscillator control signal before inputting the filtered N-bit oscillator control signal to the multiplier. 10. The digital synthesizer of claim 1 , further comprising a loop filter located after the multiplier, such that the multiplier is directly coupled to the phase comparator and the loop filter is configured to filter the N-bit oscillator control signal multiplied with the frequency-dependent gain signal. 11. A communication unit having a digital synthesizer comprising: a digitally controlled oscillator, DCO; a feedback loop; a ramp generator configured to generate a signal of frequency control words, FCW, that describes a desired frequency modulated continuous wave; and a phase comparator configured to compare a phase of the FCW output from the ramp generator and a signal fed back from the DCO via the feedback loop and output a N-bit oscillator control signal; wherein the digital synthesizer comprises a gain circuit coupled to a multiplier located between the ramp generator and the DCO and configured to apply a frequency-dependent gain signal to the N-bit oscillator control signal to maintain an open loop gain of the all-digital phase locked loop, ADPLL, and a PLL loop bandwidth that is substantially constant across a frequency modulation bandwidth, the open loop gain variations are controlled according to predefined DCO gain variations determined across a range of DCO frequencies, and the predefined DCO gain variations determined across a range of DCO frequencies are obtained through measurements of DCO gains. 12. A method for maintaining an open loop gain of an all-digital phase locked loop, ADPLL, as substantially constant across a frequency modulation bandwidth, the method comprising: generating a signal of frequency control words, FCW, that describes a desired frequency modulated continuous wave; comparing a phase of the FCW signal with a signal fed back from an output of a digital controlled oscillator, DCO, at a phase comparator and outputting a N-bit oscillator control signal from the phase comparator; generating a frequency-dependent gain signal based on the FCW; and applying the frequency-dependent gain signal to the N-bit oscillator control signal to maintain an open loop gain of the all-digital phase locked loop, ADPLL, wherein the open loop gain variations are controlled according to predefined DCO gain variations determined across a range of DCO frequencies, and the predefined DCO gain variations determined across a range of DCO frequencies are obtained through measurements of DCO gains. 13. The method of claim 12 , the method further comprising applying the frequency-dependent gain dynamically during a generation of frequency modulated continuous wave radar ramps. 14. The method of claim 12 further comprising: applying at least a first frequency to the DCO and measuring a first open loop gain value; applying at least a second frequency to the DCO and measuring a second open loop gain value; and determine therefrom open loop gain values across a range of frequency modulation bandwidths.