AD9221AR-REEL Analog Devices Inc, AD9221AR-REEL Datasheet - Page 18

AD9221AR-REEL

Manufacturer Part Number

AD9221AR-REEL

Description

IC,A/D CONVERTER,SINGLE,12-BIT,CMOS,SOP,28PIN

Manufacturer

Analog Devices Inc

Datasheet

1.AD9220ARSZ-REEL.pdf (32 pages)

Specifications of AD9221AR-REEL

Rohs Status

RoHS non-compliant

Number Of Bits

Sampling Rate (per Second)

1.5M

Data Interface

Parallel

Number Of Converters

Power Dissipation (max)

70mW

Voltage Supply Source

Single Supply

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

28-SOIC (0.300", 7.50mm Width)

For Use With

AD9221-EB - BOARD EVAL FOR AD9221

Lead Free Status / RoHS Status

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AD9221/AD9223/AD9220

Figure 19 shows the schematic of the suggested transformer

circuit. The circuit uses a Mini-Circuits RF transformer, model

#T4-6T, which has an impedance ratio of 4 (turns ratio of 2).

The schematic assumes that the signal source has a 50 Ω source

impedance. The 1:4 impedance ratio requires the 200 Ω sec-

ondary termination for optimum power transfer and VSWR.

The center tap of the transformer provides a convenient means

of level shifting the input signal to a desired common-mode

voltage. Optimum performance can be realized when the center

tap is tied to CML of the AD9221/AD9223/AD9220, which is

the common-mode bias level of the internal SHA.

Transformers with other turns ratios may also be selected to

optimize the performance of a given application. For example, a

given input signal source or amplifier may realize an improve-

ment in distortion performance at reduced output power levels

and signal swings. Therefore, selecting a transformer with a

higher impedance ratio (e.g., Mini-Circuits T16-6T with a 1:16

impedance ratio) effectively “steps up” the signal level, thus

further reducing the driving requirements of the signal source.

Referring to Figure 19, a series resistor, R

the secondary of the transformer. The values of 33 Ω and 15 pF

were selected to specifically optimize both the THD and SNR

performance of the A/D. R

tion from transients at the A/D inputs reflected back through the

primary of the transformer.

The AD9221/AD9223/AD9220 can be easily configured for

either a 2 V p-p input span or 5.0 V p-p input span by setting

the internal reference (see Table II). Other input spans can be

realized with two external gain setting resistors as shown in

, were inserted between the AD9221/AD9223/AD9220 and

Figure 18. AD9221/AD9223/AD9220 SFDR vs. Input

Frequency (V

= –0.5 dB)

–55

–65

–75

–85

–95

49.9

Figure 19. Transformer Coupled Input

MINI-CIRCUITS

T4-1

= 2.5 V, 2 V p-p Input Span,

AD9221

FREQUENCY – MHz

200

and C

AD9223

help provide some isola-

15pF

0.1 F

15pF

, and shunt capacitor,

AD9220

VINB

VINA

CML

AD9221/

AD9223/

AD9220

100

–18–

Figure 23 of this data sheet. Figure 20 demonstrates how both

spans of the AD9220 achieve the high degree of linearity and

SFDR over a wide range of amplitudes required by the most

demanding communication applications. Similar performance is

achievable with the AD9221 and AD9223 at their correspond-

ing Nyquist frequency.

Figure 20 also reveals a noteworthy difference in the SFDR and

SNR performance of the AD9220 between the 2 V p-p and 5 V p-p

input span options. First, the SNR performance improves by 2 dB

with a 5.0 V p-p input span due to the increase in dynamic

range. Second, the SFDR performance of the AD9220 will

improve for input signals below approximately –6.0 dBFS. A 3 dB

to 5 dB improvement was typically realized for input signal levels

between –6.0 dBFS and –36 dBFS. This improvement in SNR

and SFDR for a 5.0 V p-p span may be advantageous for com-

munication systems that have additional margin or headroom

to minimize clipping of the ADC.

REFERENCE CONFIGURATIONS

The figures associated with this section on internal and external

reference operation do not show recommended matching series resistors

for VINA and VINB for the purpose of simplicity. Please refer to the

Driving the Analog Inputs, Introduction section for a discussion of

this topic. Also, the figures do not show the decoupling network asso-

ciated with the CAPT and CAPB pins. Please refer to the Reference

Operation section for a discussion of the internal reference circuitry

and the recommended decoupling network shown in Figure 10.

USING THE INTERNAL REFERENCE

Single-Ended Input with 0 to 2

Figure 21 shows how to connect the AD9221/AD9223/AD9220

for a 0 V to 2 V or 0 V to 5 V input range via pin strapping the

SENSE pin. An intermediate input range of 0 to 2 × VREF can

be established using the resistor programmable configuration in

Figure 23 and connecting VREF to VINB.

In either case, both the common-mode voltage and input span

are directly dependent on the value of VREF. More specifically,

the common-mode voltage is equal to VREF while the input

span is equal to 2 × VREF. Thus, the valid input range extends

from 0 to 2 × VREF. When VINA is ≤ 0 V, the digital output

will be 000 Hex; when VINA is ≥ 2 × VREF, the digital output

will be FFF Hex.

Figure 20. AD9220 SFDR, SNR vs. Input Amplitude

= 5 MHz, f

–50

CLK

–40

= 10 MSPS, V

SFDR – 2.0V p-p

INPUT AMPLITUDE – dBFS

SFDR – 5.0V p-p

–30

SNR – 5.0V p-p

VREF Range

–20

SNR – 2.0V p-p

= 2.5 V, Differential)

–10

REV. E

AD9221AR-REEL Analog Devices Inc, AD9221AR-REEL Datasheet - Page 18

AD9221AR-REEL

Specifications of AD9221AR-REEL

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