Datasheet
DAC5686 EVALUATION BOARD
APPENDIX A. PLL LOOP FILTER COMPONENTS
DESIGNING THE PLL LOOP FILTER
R3
C3
R1
C1
C2
External Internal
S0006-01
DAC5686
SLWS147F – APRIL 2003 – REVISED JUNE 2009 ............................................................................................................................................................
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There is a combination EVM board for the DAC5686 digital-to-analog converter for evaluation. This board allows
the user the flexibility to operate the DAC5686 in various configurations. Possible output configurations include
transformer-coupled, resistor-terminated, inverting/non-inverting and differential amplifier outputs. The digital
inputs are designed to be driven directly from various pattern generators with the onboard option to add a
resistor network for proper load termination.
The DAC5686 contains an external loop filter to set the bandwidth and phase margin of the PLL. For the external
second-order filter shown in Figure 53 , the components R1, C1, and C2 are set by the user to optimize the PLL
for the application. The resistance R3 = 200 Ω and the capacitance C3 = 8 pF are internal to the DAC5686. Note
that the positions of R1 and C1 can be reversed, relative to each other.
Figure 53. DAC5686 Loop Filter
The typical VCO gain (Gvco) (the slope of VCO frequency vs voltage) as a function of VCO frequency for the
DAC5686 is shown in Figure 17 . The VCO frequency range can be extended to higher frequencies by setting the
pll_rng[1:0] registers to increase the VCO Vtol current (see Table 11 ). However, only the range for PLL_rng = 00
(nominal) is specified.
For the lowest possible phase noise, the VCO frequency should be chosen so Gvco is minimized, where
f
vco
= f
data
× Interpolation × PLL Divider
For example, if f
data
= 125 MSPS and 2 × interpolation is used, the PLL divider should be set to 2 to lock the VCO
at 500 MHz for a typical Gvco of 200 MHz/V.
The external loop filter components C1, C2, and R1 are determined by choosing Gvco, N = f
vco
/f
data
, the loop
phase margin φ
d
, and the loop bandwidth ω
d
. Except for applications where abrupt clock frequency changes
require a fast PLL lock time, it is suggested that φ
d
be set to at least 80 degrees for stable locking and
suppression of the phase-noise side lobes. Phase margins of 60 degrees or less occasionally have been
sensitive to board layout and decoupling details.
The optimum loop bandwidth ω
d
depends on both the VCO phase noise, which is largely a function of Gvco, and
the application. For the example above with Gvco = 200 MHz/V, an ω
d
= 1 MHz would be typical, but lower or
higher loop bandwidths may provide better phase noise characteristics. For a higher Gvco, for example
Gvco = 400 MHz/V, an ω
d
~ 7 MHz would be typical. However, it is suggested that customers experiment with
varying the loop bandwidth at least from × to 2 × to verify the optimum setting.
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