JAJSTV7 March 2024 DAC39RF10-SEP , DAC39RF10-SP , DAC39RFS10-SEP , DAC39RFS10-SP
PRODMIX
One of the major advantages of the DAC39RF10-Sx and 'RFS10-Sx in applications like Doppler radar, Quantum Computing and Wireless Test is the ability to directly synthesize very low phase noise signals all the way through X-band (12GHz). To take full advantage of the exceptionally low additive phase noise of the DAC, a high-performance clock is required.
Equally important in most systems is the impact of Size, Weight, Area, Power and Cost (SWAP-C). This means each system architect must weight tradeoffs in performance vs. overall system SWAP-C based on system requirements. This section presents three clocking examples based on SWAP-C vs. performance tradeoffs.
Figure 8-6 shows a plot of phase noise for an 8GHz sample clock produced by an integrated PLL+VCO, integrated PLL with external high performance VCO and a fully discrete high performance analog PLL. All examples assume a reference clock is provided as an input to the synthesizer, which can range from low cost surface mount crystal oscillators all the way to expense reference subsystems. The DAC39RF10-Sx and 'RFS10-Sx additive phase noise at 8GHz is also provided for comparison , even for the analog PLL, the clock phase noise degrades the DAC39RF10-Sx and 'RFS10-Sx output phase noise for offset frequencies below 5MHz.