ADA4817-1ARD-EBZ Analog Devices, ADA4817-1ARD-EBZ Datasheet - Page 16

ADA4817-1ARD-EBZ

Manufacturer Part Number

ADA4817-1ARD-EBZ

Description

Amplifier IC Development Tools ADA4817-1AR-EBZ_A00973_EB-O8REDF-1Z

Manufacturer

Analog Devices

Type

High Speed Amplifiersr

Series

ADA4817r

Datasheet

1.ADA4817-1ARD-EBZ.pdf (28 pages)

Specifications of ADA4817-1ARD-EBZ

Rohs

yes

Product

Evaluation Boards

Tool Is For Evaluation Of

ADA4817-1ARDZ

Operating Supply Voltage

5 V to 10 V

Description/function

8 lead SOIC bare evaluation board

Maximum Operating Temperature

+ 105 C

Minimum Operating Temperature

- 40 C

Operating Supply Current

19 mA

Factory Pack Quantity

For Use With

ADA4817

Current page: 16 of 28
Download datasheet (540Kb)

ADA4817-1/ADA4817-2

Table 8. Power-Down Voltage Control

PD Pin

Not active

Active

CAPACITIVE FEEDBACK

Due to package variations and pin-to-pin parasitics between the

single and the dual models, the ADA4817-2 has a little more

peaking then the ADA4817-1, especially at a gain of 2. The best

way to tame the peaking is to place a feedback capacitor across

the feedback resistor. Figure 46 shows the small signal frequency

response of the ADA4817-2 at a gain of 2 vs. C

was used to show the peaking, but then two other values of

0.5 pF and 1 pF were used to show how to reduce the peaking or

even eliminate it. As shown in Figure 46, if the power consumption

is a factor in the system, then using a larger feedback capacitor

is acceptable as long as a feedback capacitor is used across it to

control the peaking. However, if power consumption is not an

issue, then a lower value feedback resistor, such as 200 Ω, would

not require any additional feedback capacitance to maintain

flatness and lower peaking.

HIGHER FREQUENCY ATTENUATION

There is another package variation problem between the SOIC

and the LFCSP package. The SOIC package shows approximately

1 dB to 1.5 dB of additional peaking at a gain of 1. This is due to

the parasitic in the SOIC package, which is not recommended

for very high frequency parts that exceed 1 GHz. A good approach

to reducing the peaking is to place a resistor, R

the noninverting input. This creates a first-order pole formed

by R

Figure 46. Small Signal Frequency Response vs. Feedback Capacitor

and C

–3

–6

–9

G = 2

OUT

, the common-mode input capacitance.

= 348Ω

= 10V

= 100Ω

= 100mV p-p

10M

±5 V

>4 V

<2 V

(ADA4817-2)

FREQUENCY (Hz)

= 0.5pF

= 1pF

100M

+3 V, −2 V

>2 V

<0 V

NO C

, in series with

. At first, no C

10G

Rev. B | Page 16 of 28

Figure 47 shows the higher frequency attenuation, which

reduces the peaking but also reduces the −3 dB bandwidth.

As shown in Figure 47, the peaking dropped by almost 2 dB

when R

dropped from 1 GHz to 700 MHz. To maintain the −3 dB

bandwidth and to reduce peaking, an RLC circuit is recommended

instead of R

The R in parallel to the series LC forms a notch that can be

shaped to compensate for the peaking produced by the amplifier.

The result is a smooth 1 GHz −3 dB bandwidth, 250 MHz 0.1 dB

flatness, and less than 1 dB of peaking. This circuit should be

placed in the path of the noninverting input when the ADA4817-x

is used at a gain of 1. The RLC values may need tweaking

depending on the source impedance and the flatness and band-

width required. Figure 49 shows the frequency response after the

RLC circuit is in place.

Figure 47. Small Signal Frequency Response for Various R

–3

–6

–9

–3

–6

–9

= 0 Ω to R

G = 1

OUT

, as shown in Figure 48.

Figure 49. Frequency Response with RLC Circuit

= 100Ω

= ±5V

= 100Ω

= 10V

= 0.1V p-p

= 100mV p-p

= 100 Ω, and in return, the −3 dB bandwidth

10M

Figure 48. RLC Circuit

10nH

FREQUENCY (Hz)

120Ω

100M

2pF

= 100Ω

RLC

Data Sheet

NO RLC

= 75Ω

= 50Ω

= 0Ω

(SOIC)

10G

ADA4817-1ARD-EBZ Analog Devices, ADA4817-1ARD-EBZ Datasheet - Page 16

ADA4817-1ARD-EBZ

Specifications of ADA4817-1ARD-EBZ

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