ZHCSTG5 October 2023 ADC12QJ1600-SEP
PRODUCTION DATA
The device requires two different power-supply voltages. 1.9 V DC is required for the VA19, VPLL19 and VREFO power buses and 1.1 V DC is required for the VA11 and VD11 power buses. VTRIG can be set to either 1.1 V or 1.9 V and the TRIGOUT± common mode voltage shifts accordingly.
The power-supply voltages must be low noise and provide the needed current to achieve rated device performance. Certain supplies should be isolated from each other to prevent noise coupling into sensitive supplies. Isolation is best performed using separate regulators for each supply, but this is often not possible due to size and cost constraints. At a minimum a PI-type power supply filtering scheme should be used which includes a low-DC resistance ferrite bead (FB) with low-inductance decoupling capacitors on each side of the ferrite bead. These are demonstrated in the example power supply architectures drawings in Figure 7-3 and Figure 7-4.
There are two recommended power supply architectures:
The WEBENCH® Power Designer can be used to select and design the individual power supply elements as needed.
Recommended switching regulators include the TPS62913, TPS62912, TPS62085, and similar devices.
Recommended Low Drop-Out (LDO) linear regulators include the TPS7A8400, TPS7A7200, TPS7A54 and similar devices.
For the switcher only approach, the ripple filter must be designed to provide sufficient filtering at the switching frequency of the DC-DC converter and harmonics of the switching frequency. Make a note of the switching frequency reported from WEBENCH® and design the EMI filter and capacitor combination to have the filter cutoff frequency set as needed. Each application has different tolerance for noise on the supply voltage and the impact to performance so strict ripple requirements are not provided. In general, the supply voltage must stay within the recommended operating conditions limits during all ripple and transient events. Any supply filtering must account for potential current transients, specifically when using low-power background calibration (see Low-Power Background Calibration (LPBG) Mode).