AD8045ARDZ-REEL7(RevB) データシートの表示（PDF） - Analog Devices

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AD8045ARDZ-REEL7
(Rev.:RevB)

3 nV/√Hz, Ultralow Distortion, High Speed Op Amp

Analog Devices 

AD8045

0

AIN = –1dBFS

SNR = 69.9dBc

SFDR = 65.3dBc

–20

–40

–60

–80

–100

–120

0

5

10

15

20

25

30

FREQUENCY (MHz)

Figure 69. Single-Tone FFT, FIN = 50 MHz, Sample Rate = 65 MSPS

Shown in the First Nyquist Zone

90 MHZ ACTIVE LOW-PASS FILTER (LPF)

Active filters are used in many applications such as antialiasing

filters and high frequency communication IF strips.

With a 400 MHz gain bandwidth product and high slew rate, the

AD8045 is an ideal candidate for active filters. Figure 70 shows

the frequency response of the 90 MHz LPF. In addition to the

bandwidth requirements, the slew rate must be capable of

supporting the full power bandwidth of the filter. In this case,

a 90 MHz bandwidth with a 2 V p-p output swing requires at

least 1200 V/µs. This performance is achievable only at 90 MHz

because of the wide bandwidth and high slew rate of the AD8045.

The circuit shown in Figure 73 is a 90 MHz, 4-pole, Sallen-Key,

LPF. The filter comprises two identical cascaded Sallen-Key LPF

sections, each with a fixed gain of G = +2. The net gain of the filter

is equal to G = +4 or 12 dB. The actual gain shown in Figure 70

is only 6 dB. This is due to the output voltage being divided in

half by the series matching termination resistor, RT, and the

load resistor.

Data Sheet

Setting the resistors and capacitors equal to each other greatly

simplifies the design equations for the Sallen-Key filter. The

corner frequency, or −3 dB frequency, can be described by the

equation

fc

=

1

2πRC

The quality factor, or Q, is shown in the equation

Q

=

3

1

−K

The gain, or K, of the circuits is

First

Stage

K

=

R3

R4

+ 1,

Second

Stage

K

=

R8

R7

+1

Resistor values are kept low for minimal noise contribution,

offset voltage, and optimal frequency response. Due to the low

capacitance values used in the filter circuit, the PCB layout and

minimization of parasitics is critical. A few picofarads can detune

the filters corner frequency, fc. The capacitor values shown in

Figure 73 actually incorporate some stray PCB capacitance.

Capacitor selection is critical for optimal filter performance.

Capacitors with low temperature coefficients, such as NPO

ceramic capacitors and silver mica, are good choices for filter

elements.

20

10

0

–10

–20

–30

–40

–50

–60

–70

–80

–90

0.1

1

10

100

FREQUENCY (MHz)

1000

Figure 70. 90 MHz Low-Pass Filter Response

Rev. B | Page 20 of 24

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