SLAS969D January 2014 – October 2017 ADC12J1600 , ADC12J2700
PRODUCTION DATA.
NOTE
Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality.
The ADC12J1600 and ADC12J2700 devices are a wideband sampling and digital tuning device. The ADC input captures input signals from DC to greater than 3 GHz. The DDC performs digital-down conversion and programmable decimation filtering, and outputs complex (15 bit I and 15 bit Q) data. In DDC Bypass Mode (Decimation = 1) the raw 12 bit ADC data is also available. The resulting output data is output on the JESD204B data interface for capture by the downstream capture or processing device. Most frequency-domain applications benefit from DDC capability to select the desired frequency band and provide only the necessary bandwidth of output data, minimizing the required number of data signals. Time domain applications generally require the raw 12-bit ADC output data provided by the DDC bypass feature.
An RF Sampling Receiver is used to directly sample a signal in the RF frequency range and provide the data for the captured signal to downstream processing. The wide input bandwidth, high sampling rate, and DDC features of the ADC12J1600 and ADC12J2700 make them ideally suited for this application.
For this design example, use the parameters listed in Table 87.
DESIGN PARAMETERS | EXAMPLE VALUES |
---|---|
Signal center frequency | 2500 MHz |
Signal bandwidth | 100 MHz |
Signal nominal amplitude | –7 dBm |
Signal maximum amplitude | 6 dBm |
Minimum SINAD (in bandwidth of interest) | 48 dBc |
Minimum SFDR (in bandwidth of interest) | 60 dBc |
Use the following steps to design the RF receiver:
The LMK048xx JESD204B clocking devices can provide the DEVCLK clock and other system clocks for ƒ(DEVCLK) < 3101 MHz.
For DEVCLK frequencies up to 4 GHz the consider using the LMX2581 and TRF3765 devices as the DEVCLK source. Use the LMK048xx device to provide the JESD204B clocks. For additional device information, see the Related Documentation section.
The following curves show an RF signal at 2497.97 MHz captured at a sample rate of 1600 MSPS. Figure 110 shows the spectrum for the full Nyquist band. Figure 111 shows the spectrum for the output data in decimate-by-32 mode with ƒ(NCO) equal to 700 MHz. Figure 111 shows the ability to provide only the spectrum of interest in the decimated output data. Figure 111 also shows how proper selection of the sampling rate can ensure interleaving tones are outside the band of interest and outside the decimated frequency range. Lastly, Figure 111 shows the reduction in the noise floor provided by the processing gain of decimation.
DDC Bypass Mode | ƒS = 1600 MSPS | |
FIN = 2497.97 MHz at –1 dBFS |
ƒS = 1600 MSPS | ƒ(NCO) = 2500 MHz | |
FIN = 2497.97 MHz at –1 dBFS |
The ADC12J1600 and ADC12J2700 devices are equally well-suited for high-speed time-domain applications such as oscilloscopes. The following typical application is for a generic high-speed oscilloscope. Adjustable gain is provided by the front-end resistor ladder and selection mux, and the gain adjustments of the LMH6518 device. Additional gain fine-tuning can be achieved using the full-scale range adjustment features of the ADC.
For this design example, use the parameters listed in Table 88.
DESIGN PARAMETERS | EXAMPLE VALUES |
---|---|
Maximum sample rate | 1600 MSPS |
Maximum input frequency | 1500 MHz |
1-dB flat-frequency range | 0 to 1000 MHz |
Signal maximum amplitude | 6 dBm |
Signal minimum amplitude | 48 dBc |
Maximum capture depth | 1 million points |
Use the following primary steps to design a 12-bit oscilloscope:
The following curves show the time-domain sample data for a 150-MHz input signal at –1 dBFS, sampled at 1600 MSPS using the ADC12J1600 device. Figure 113 shows the raw time-domain data. Figure 114 shows the spectrum of the captured signal which shows the additional capability of a 12-bit ADC oscilloscope to provide basic spectrum-analysis functions with reasonable performance.
FIN = 147.97 MHz at –1 dBFS | ƒS = 1600 MSPS |
FIN = 147.97 MHz at –1 dBFS | ƒS = 1600 MSPS |
The JESD204B interface requires a specific startup and alignment sequence. The general order of that sequence is listed in the following steps.
NOTE
If deterministic latency is not required this step can be omitted.
Driving the inputs (analog or digital) beyond the power supply rails. For device reliability, an input must not go more than 150 mV below the ground pins or 150 mV above the supply pins. Exceeding these limits even on a transient basis can cause faulty, or erratic, operation and can impair device reliability. High-speed digital circuits exhibiting undershoot that goes more than a volt below ground is common. To control overshoot, the impedance of high-speed lines must be controlled and these lines must be terminated in the characteristic impedance.
Care must be taken not to overdrive the inputs of the ADC12J1600 and ADC12J2700 devices. Such practice can lead to conversion inaccuracies and even to device damage.
Incorrect analog input common-mode voltage in the DC-coupled mode. As described in the The Analog Inputs and DC Coupled Input Usage sections, the input common-mode voltage (VCMI) must remain the specified range as referenced to the VCMO pin, which has a variability with temperature that must also be tracked. Distortion performance is degraded if the input common mode voltage is outside the specified VCMI range.
Using an inadequate amplifier to drive the analog input. Use care when choosing a high frequency amplifier to drive the ADC12J1600 and ADC12J2700 devices because many high-speed amplifiers have higher distortion than the ADC12J1600 and ADC12J2700 devices which results in overall system performance degradation.
Driving the clock input with an excessively high level signal. The ADC input clock level must not exceed the level described in the Recommended Operating Conditions table because the input offset can change if these levels are exceeded.
Inadequate input clock levels. As described in the Using the Serial Interface section, insufficient input clock levels can result in poor performance. Excessive input-clock levels can result in the introduction of an input offset.
Using a clock source with excessive jitter, using an excessively long input clock signal trace, or having other signals coupled to the input clock signal trace. These pitfalls cause the sampling interval to vary which causes excessive output noise and a reduction in SNR performance.
Failure to provide adequate heat removal. As described in the Thermal Management section, providing adequate heat removal is important to ensure device reliability. Adequate heat removal is primarily provided by properly connecting the thermal pad to the circuit board ground planes. Multiple vias should be arranged in a grid pattern in the area of the thermal pad. These vias will connect the topside pad to the internal ground planes and to a copper pour area on the opposite side of the printed circuit board.