AD6600ST/PCB Analog Devices Inc, AD6600ST/PCB Datasheet - Page 16

AD6600ST/PCB

Manufacturer Part Number

AD6600ST/PCB

Description

BOARD EVAL ADC RSSI W/AD6600AST

Manufacturer

Analog Devices Inc

Datasheet

1.AD6600ASTZ-REEL.pdf (24 pages)

Specifications of AD6600ST/PCB

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AD6600

Attenuator

0 dB

–12 dB

–24 dB

High-Speed Peak Detector and RSSI Circuitry

The peak detector along with the attenuator and dual gain

amplifier form the control loop within the AD6600.

The peak detector is designed to follow the analog input one clock

cycle before the conversion is actually made. Therefore, while the

converter section of the AD6600 is converting sample “n,” the

peak detector is already looking at sample “n+1.” While look-

ing at the “n+1” sample (the calibration period), the peak detec-

tor examines the envelope of the input signal. The more of an

envelope that is tracked, the more accurate the gain setting. At

the very least, the peak detector must be presented either a positive

or negative sinusoidal peak, which represents about one-half of a

sine wave cycle. Since the peak detector works for a complete cycle

prior to conversion, the absolute minimum IF frequency that can

be determined is twice the sample rate per channel. Therefore,

at 15 MSPS, the minimum IF frequency that can be sampled

would be 30 MHz.

Note that the more cycles of the input that are monitored by the

peak detector, the more accurate the gain setting will be. There-

fore, the actual minimum IF frequency recommended is higher

than this. The minimum specified frequency is 70 MHz. Since the

RSSI control loop is performed on a sample-by-sample basis,

the AD6600 very accurately follows the signals into and out of a

deep fade.

Hysteresis

The AD6600 employs hysteresis to prevent the gain-ranging from

unnecessarily changing when the signal envelope is near an RSSI

threshold. The hysteresis is digital and will account for exactly

6 dB of shift, depending on whether the signal is increasing or

decreasing. This effect is shown in the dashed lines of the over-

all transfer function, Figure 16.

External LC Noise Filter, Resonant Port

The output of the attenuator/gain stage drives the wide bandwidth

track-and-hold (T/H), followed by the ADC encoder. Because the

attenuator/gain stage has a very wide bandwidth (~1 GHz), an

LC filter or “resonant port” is provided to limit the amount of

wideband noise delivered to the ADC. The simple LC filter does

not provide signal selectivity and should typically be 35 MHz to

50 MHz wide. However, because the ADC’s track-and-hold itself

has a wide bandwidth (~450 MHz), this noise-limiting filter is

critical to meeting overall sensitivity. Specific details on select-

ing components for the resonant port are provided later in the

text (Understanding the External Analog Filter).

Table I. Attenuator and Gain Settings

Gain Amp

+18 dB

+12 dB

+18 dB

+12 dB

+18 dB

+12 dB

Total

+18 dB

+12 dB

+6 dB

0 dB

–6 dB

–12 dB

RSSI Word

000

001

010

011

100

101

ADC Encoder

After the calibration period is complete (one clock cycle), the

appropriate gain and attenuator settings are determined and set.

Once settled, the internal track-and-hold freezes the input signal

so that the ADC encoder may digitize the signal. During digiti-

zation, the peak detector/RSSI circuitry is already looking at the

next sample. When the AD6600 is in dual channel mode, the

process is interleaved: while Channel B is monitored for signal

strength, Channel A is digitized. This allows the RSSI to update

on a clock-by-clock basis.

Figure 17 shows the internal timing of the chip. The encode

applied to the device initiates several actions. The first and most

important is that the track-and-hold is placed in hold, thus

sampling the analog input at that instant. The second action is that

the peak detector of the RSSI circuitry is initialized. During this

period, the analog input envelope is monitored to determine signal

power. The AD6600 is in calibration mode for about one-

quarter of the encode period.

While the AD6600 is in calibration, the external noise filter is

discharged and the amplifier driving the filter disabled. Since this

filter is shared between the two input channels in dual channel

mode, this greatly reduces the feedthrough between the channels

that would otherwise exist. One-quarter of an encode period after

the calibration is complete, the amplifier is re-enabled and allowed

to settle to its new signal conditions for sampling by the wideband

T/H on the next encode signal. The final action is that the signal

on the resonant port is sampled by the track-and-hold. This

happens on the next rising edge of the encode.

Input Mode Select

The AD6600 has two operating modes: single channel and dual

channel. In single channel mode, the ADC always samples Chan-

nel A or always samples Channel B. In dual channel mode, the

ADC converter is sampling Channel A and Channel B on alter-

nating Encode cycles. Two control pins are provided to select

the desired mode of operation. A_SEL and B_SEL arbitrate the

selection of how these input channels are connected to the out-

put. Table II shows the truth table for selection of the input.

CALIBRATION

AMPLIFIER

INTERNAL

CONTROL

T/H INPUT

ENCODE

IF INPUT

CLOCK

RSSI

T-AND-H HOLD

RSSI

CAL.

NOISE FILTER

DISCHARGE

OLD DATA

DIGITIZE

CLAMPED

4/8 AMP

RSSI SET

T-AND-H TRACK

NOISE FILTER

SETTLING

NOISE FILTER

SETTLING

T-AND-H HOLD

ADC DIGITIZE

AD6600ST/PCB Analog Devices Inc, AD6600ST/PCB Datasheet - Page 16

AD6600ST/PCB

Specifications of AD6600ST/PCB

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