ADL5391_技术文档

DC to 2.0 GHz

Multiplier

ADL5391

FUNCTIONAL BLOCK DIAGRAM

FEATURES

YMNS YPLS

GADJ

Ultrafast symmetric multiplier

Function: V_W= α × (V_X× V_Y)/1 V + V_Z

Unique design ensures absolute XY-symmetry

Identical X and Y amplitude/timing responses

Adjustable gain scaling, α

XPLS

XMNS

ZMNS

ZPLS

WPLS

DC-coupled throughout, 3 dB bandwidth of 2 GHz

Fully differential inputs, may be used single ended

Low noise, high linearity

ENBL

VMID

WMNS

ADL5391

W = αXY/1V+Z

Accurate, temperature stable gain scaling

Single-supply operation (4.5 V to 5.5 V @ 130 mA)

Low current power-down mode

COMM VPOS

Figure 1.

16-lead LFCSP

APPLICATIONS

Wideband multiplication and summing

High frequency analog modulation

Adaptive antennas (diversity/phased array)

Square-law detectors and true rms detectors

Accurate polynomial function synthesis

DC capable VGA with very fast control

GENERAL DESCRIPTION

are ac-coupled, their nominal voltage will be V_POS/±. These input

interfaces each present a differential 500 Ω input impedance up to

approximately 700 MHz, decreasing to 50 Ω at ± GHz. The gain

scaling input, GADJ, can be used for fine adjustment of the gain

scaling constant (α) about unity.

The ADL5391 draws on three decades of experience in

advanced analog multiplier products. It provides the same

general mathematical function that has been field proven to

provide an exceptional degree of versatility in function synthesis.

V

_W= α × (V_X× V_Y)/ 1 V + V_Z

The differential output can swing ±± V about the V_POS/±

common-mode and can be taken in a single-ended fashion as

well. The output common mode is designed to interface directly

to the inputs of another ADL5391. Light dc loads can be ground

referenced; however, ac-coupling of the outputs is recommended

for heavy loads.

The most significant advance in the ADL5391 is the use of a

new multiplier core architecture, which differs markedly from

the conventional form that has been in use since 1970. The

conventional structure that employs a current mode, translinear

core is fundamentally asymmetric with respect to the X and Y

inputs, leading to relative amplitude and timing misalignments

that are problematic at high frequencies. The new multiplier

core eliminates these misalignments by offering symmetric

signal paths for both X and Y inputs. The Z input allows a signal

to be added directly to the output. This can be used to cancel a

carrier or to apply a static offset voltage.

The ENBL pin allows the ADL5391 to be disabled quickly to a

standby mode. It operates off supply voltages from 4.5 V to

5.5 V while consuming approximately 130 mA.

The ADL5391 is fabricated on Analog Devices proprietary, high

performance, 65 GHz, SOI complementary, SiGe bipolar IC

process. It is available in a 16-lead, Pb-free, LFCSP and operates

over a −40°C to +85°C temperature range. Evaluation boards

are available.

The fully differential X, Y, and Z input interfaces are operational

over a ±± V range, and they can be used in single-ended fashion.

The user can apply a common mode at these inputs to vary

from the internally set V_POS/± down to ground. If these inputs

Rev. 0

Information furnished by Analog Devices is believed to be accurate and reliable. However, no

responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other

rights of third parties that may result from its use. Specifications subject to change without notice. No

license is granted by implication or otherwise under any patent or patent rights of Analog Devices.

Trademarks and registeredtrademarks arethe property of their respective owners.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 781.329.4700

Fax: 781.461.3113

www.analog.com

ADL5391

TABLE OF CONTENTS

Features .............................................................................................. 1

Typical Performance Characteristics ..............................................7

General Description....................................................................... 10

Basic Theory ............................................................................... 10

Basic Connections...................................................................... 10

Evaluation Board ............................................................................ 13

Outline Dimensions....................................................................... 15

Ordering Guide .......................................................................... 15

Applications....................................................................................... 1

Functional Block Diagram .............................................................. 1

General Description......................................................................... 1

Revision History ............................................................................... ±

Specifications..................................................................................... 3

Absolute Maximum Ratings............................................................ 5

ESD Caution.................................................................................. 5

Pin Configuration and Function Descriptions............................. 6

REVISION HISTORY

7/06—Revision 0: Initial Version

Rev. 0 | Page 2 of 16

ADL5391

SPECIFICATIONS

V_POS= 5 V, T_A= ±5°C, Z_L= 50 Ω differential, ZPLS = ZMNS = open, GADJ = open, unless otherwise noted. Transfer function: W =

XY/1 V + Z, common mode internally set to ±.5 V nominal.

Table 1.

Parameter

Conditions

Min Typ

Max Unit

MULTIPLICAND INPUTS (X, Y)

Differential Voltage Range

Common-Mode Range

Input Offset Voltage

vs. Temperature

XPLS, XMNS, YPLS, YMNS

Differential, common mode = 2.5 V

For full differential range

DC

−40°C to +85°C

f = dc

2

V p-p

V

mV

Ω

0

2.5

20

Differential Input Impedance

500

150

−42

f = 2 GHz

Ω

dB

Fundamental Feedthrough, X or Y

Gain

f = 50 MHz, X (Y) = 0 V, Y (X) = 0 dBm, relative to

condition where X (Y) = 1 V

f = 1 GHz

X = 50 MHz and 0 dBm, Y = 1 V

X = 1 GHz and 0 dBm, Y = 1 V

X to output, Y = 1 V

X = Y = 1 V

1 V p-p, Y = 1 V, f = 50 MHz

ZPLS, ZMNS

Common mode from 2.5 V down to COMM

For full differential range

From Z to W, f ≤ 10 MHz, 0 dBm, X = Y = 1 V

f = dc

−35

0.5

−1.33

1

dB

% FS

V/V

dB

DC Linearity

Scale Factor

CMRR

42.1

SUMMING INPUT (Z)

Differential Voltage Range

Common-Mode Range

Gain

2

V p-p

V

dB

Ω

0

2.5

0.1

500

150

Differential Input Impedance

f = 2 GHz

Ω

OUTPUTS (W)

WPLS, WMNS

Differential Voltage Range

Common-Mode Output

Output Noise Floor

No external common mode

2

V

V_POS− 2.5

X = Y = 1 V dc

f = 1 MHz

f = 1 GHz

−133

dBm/Hz

X = Y = 0

f = 1 MHz

f = 1 GHz

X = Y = 0, f = 1 MHz

Z = 0 V differential

−138

26.7

19

dBm/Hz

nV/√Hz

mV

Output Noise Voltage Spectral Density

Output Offset Voltage

vs. Temperature

19

mV

Differential Output Impedance

f = dc

0

Ω

f = 200 MHz

f = 2 GHz

75

500

Ω

DYNAMIC CHARACTERISTICS

Frequency Range

Slew Rate

Settling Time

Second Harmonic Distortion

X, Y, Z to W

0

2

GHz

V/μs

ns

dBc

W from −2.0 V to +2.0 V, 150 Ω

X stepped from −1 V to +1 V, Z = 0 V, 150 Ω

X (Y) = 0 dBm, Y (X) = 1 V, fund = 10 MHz

Fund = 200 MHz

X (Y) = 0 dBm, Y (X) = 1 V, fund = 10 MHz

Fund = 200 MHz

8800

2.1

−60

−51

−61.5

−51.6

Third Harmonic Distortion

Rev. 0 | Page 3 of 16

ADL5391

Parameter

Conditions

Min Typ

Max Unit

OIP3

Two-tone IP3 test; X (Y) = 100 mV p-p/tone

(−10 dBm into 50 Ω), Y (X) = 1

f1= 49 MHz, f = 50 MHz

f1 = 999 MHz, f2 = 1 GHz

f1 = 49 MHz, f = 50 MHz

f1 = 999 MHz, f2 = 1 GHz

X (Y) to W, Y (X) = 1 V, 50 MHz

1 GHz

26.5

14

45.5

28

15.1

13.2

0.5

dBm

ns

OIP2

Output 1 dB Compression Point

Group Delay

200 MHz

1 GHz

0.7

ns

Differential Gain Error, X/Y

Differential Phase Error, X/Y

GAIN TRIMMING (α)

Nominal Bias

f = 3.58 MHz

2.7

0.23

%

Degrees

GADJ

Unconnected

1.12

V

Input Range

0

2

V

Gain Adjust Range

REFERENCE VOLTAGE

Source Current

Input 0 V to 2 V

9.5

dB

V

mA

VMID

V_POS/2

Common-mode for X, Y, Z = 2.5 V

V_POS, COMM, ENBL

50

POWER AND ENABLE

Supply Voltage Range

Total Supply Current

Disable Current

Disable Threshold

Enable Response Time

4.5

5.5

V

Common-mode for X, Y, Z = 2.5 V

ENBL = 0 V

High to Low

Delay following high-to-low transition until device

meets full specifications

135

7.5

1.5

mA

V

150

ns

Disable Response Time

Delay following low-to-high transition until device

produces full attenuation

50

ns

Rev. 0 | Page 4 of 16

ADL5391

ABSOLUTE MAXIMUM RATINGS

Table 2.

Parameter

Rating

Stresses above those listed under Absolute Maximum Ratings

may cause permanent damage to the device. This is a stress

rating only; functional operation of the device at these or any

other conditions above those indicated in the operational

section of this specification is not implied. Exposure to absolute

maximum rating conditions for extended periods may affect

device reliability.

Supply Voltage V_POS

ENBL

XPLS, XMNS, YPLS, YMNS, ZPLS, ZMNS

GADJ

Internal Power Dissipation

θ_JA(With Pad Soldered to Board)

Maximum Junction Temperature

Operating Temperature Range

Storage Temperature Range

Lead Temperature (Soldering 60 sec)

5.5 V

V_POS

800 mW

73°C/W

150°C

−40°C to +85°C

−65°C to +150°C

300°C

ESD CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on the

human body and test equipment and can discharge without detection. Although this product features

proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy

electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance

degradation or loss of functionality.

Rev. 0 | Page 5 of 16

ADL5391

PIN CONFIGURATION AND FUNCTION DESCRIPTIONS

PIN 1

INDICATOR

12 YMNS

11 YPLS

10 ZPLS

COMM

VPOS

1

2

3

4

ADL5391

9

ZMNS

Figure 2. Pin Configuration

Table 3. Pin Function Descriptions

Pin No.

Mnemonic

Description

1, 7

2 to 4

5, 6

COMM

V_POS

WPLS, WMNS

GADJ

Device Common. Connect via lowest possible impedance to external circuit common.

Positive Supply Voltage. 4.5 V to 5.5 V.

Differential Outputs.

8

Denominator Scaling Input.

9, 10

11, 12

13, 14

15

ZMNS, ZPLS

YPLS, YMNS

XPLS, XMNS

ENBL

Differential Intercept Inputs. Must be ac-coupled. Differential impedance 50 Ω nominal.

Differential X-Multiplicand Inputs.

Differential Y-Multiplicand Inputs.

Chip Enable. High to enable.

16

VMID

V_POS/2 Reference Output. Connect decoupling capacitor to circuit common.

Rev. 0 | Page 6 of 16

ADL5391

TYPICAL PERFORMANCE CHARACTERISTICS

GADJ = open.

3.0

14

12

10

8

200

150

100

50

Y = –2

Y = –1

Y = 0

Y = +1

Y = +2

2.5

2.0

1.5

6

1.0

4

0.5

2

0

–0

–2

–4

–6

–8

–10

–12

–14

–0.5

–1.0

–1.5

–2.0

–2.5

–3.0

–50

–100

–150

–200

–2.5 –2.0 –1.5 –1.0 –0.5

0

0.5

)

1.0

1.5

2.0

2.5

0.20

2.0

X

(V

DC

DIFF

FREQUENCY (MHz)

Figure 3. Full Range DC Cross Plots

Figure 6. Gain and Phase vs. Frequency of X Swept and Y = 1 V, Z = 0 V,

_IN= 0 dBm

P

0.20

0.15

0.10

0.05

0

4

3

200

150

100

50

2

1

0

–0

–0.05

–0.10

–0.15

–0.20

–1

–2

–3

–4

–50

–100

–150

–200

Y = –2

Y = –1

Y = 0

Y = +1

Y = +2

–0.20 –0.15 –0.10 –0.05

0

0.05

0.10

0.15

X

(V

)

DIFF

DC

FREQUENCY (MHz)

Figure 7. Gain and Phase vs. Frequency of Z Inputs, X = 0 V, Y = 0 V,

_IN= 0 dBm

Figure 4. Magnified DC Cross Plots

P

2.0

1.5

2.5

2.0

1.5

1.0

0.5

0

X ± INPUT = 1.0V p-p, @ 200MHz

Y ± INPUT = 1.0V DC DIFFERENTIAL

1.0

0.5

0

–0.5

–1.0

–1.5

–2.0

24.5 25.5 26.5 27.5 28.5 29.5 30.5 31.5 32.5 33.5

–1.0

–0.5

0

0.5

1.0

1.5

TIME (ns)

GADJ (V

)

DC

Figure 5. Gain vs. GADJ (X = Y = 1)

Figure 8. Large Signal Pulse Response

Rev. 0 | Page 7 of 16

ADL5391

0.20

0.15

0.10

0.05

0

30

25

20

15

10

5

X ± INPUT = ±100mV p-p, @ 200MHz

Y ± INPUT = 1.0V DC DIFFERENTIAL

Y = 1

Y = 0.5

–0.05

–0.10

–0.15

–0.20

24.5

0

25.5

26.5

27.5

28.5

29.5

30.5

31.5

32.5

0

500

1000

FREQUENCY (MHz)

1500

2000

TIME (ns)

Figure 9. Small Signal Pulse Response

Figure 12. OIP3 vs. Frequency

Pin 0 dBm, Y = 1 V dc, 0.5 V dc

0.05

0.04

0.03

0.02

0.01

0

+85°C, X = +1

+85°C, X = –1

–40°C, X = –1

–40°C, X = +1

+25°C, X = –1

+25°C, X = +1

10MHz

200MHz

–0.01

–0.02

–0.03

–0.04

–0.05

400MHz

600MHz

30MHz

20MHz

–0.05 –0.04 –0.03 –0.02 –0.01

0

0.01 0.02 0.03 0.04 0.05

Y

(V )

DC

DIFF

Figure 10. Harmonic Distortion at 10 MHz and 200 MHz;

0 dBm Input to X (Y) Channels

Figure 13. Z (W) Offset Over Temperature

28

45

40

35

30

25

20

15

X = 0V, Y = 1V

26

24

22

20

18

16

14

12

10

X = Y = 1V

X = Y = 0V

–40

–15

10

35

60

85

200

400

600

800 1000 1200 1400 1600 1800 2000

FREQUENCY (MHz)

TEMPERATURE (°C)

Figure 11. X ( Y) Offset Drift vs. Temperature

Figure 14. Noise vs. Frequency

Rev. 0 | Page 8 of 16

ADL5391

S22 SE

S11 SE

1.00UFS

S11 DIFF

S22 DIFF

1.000

3001.000

1.000

3001.000

201.000

1001.000

1901.000

0.654 U

0.594 U

0.531 U

–36.340 DEG

–92.533 DEG

–94.448 DEG

201.000

1001.000

1901.000

0.947 U

0.569 U

0.597 U

+170.736 DEG

+58.257 DEG

–69.673 DEG

201.000

2001.000

0.800 U

0.564 U

–17.218 DEG

–58.167 DEG

201.000

2001.000

0.905 U

0.663 U

+157.308 DEG

–39.468 DEG

Figure 15. Input S11

Figure 16. Output S22

Rev. 0 | Page 9 of 16

ADL5391

GENERAL DESCRIPTION

The small-signal bandwidth from the inputs X, Y, and Z to

the output W is a single-pole response. The pole is inversely

proportional to α. For α = 1 (GADJ floating), the bandwidth is

about ± GHz; for α > 1, the bandwidth is reduced; and for α < 1,

the bandwidth is increased.

BASIC THEORY

The multiplication of two analog variables is a fundamental

signal processing function that has been around for decades.

By convention, the desired transfer function is given by

W = αXY/U + Z

(1)

All input ports, X, Y, and Z, are differential and internally

biased to midsupply, V_POS/±. The differential input impedance is

500 Ω up to 100 MHz, rolling off to 50 ꢀ at ± GHz. All inputs

can be driven in single-ended fashion and can be ac-coupled. In

dc-coupled operation, the inputs can be biased to a common

mode that is lower than V_POS/±. The bias current flowing out of

the input pins to accommodate the lower common mode is

subtracted from the 50 mA total available from the internal

reference V_POS/± at the VREF pin. Each input pin presents an

equivalent ±50 ꢀ dc resistance to V_POS/±. If all six input pins sit

1 V below V_POS/±, a total of 6 × 1 V/±50 Ω = ±4 mA must flow

internally from VREF to the input pins.

where:

X and Y are the multiplicands.

U is the multiplier scaling factor.

α is the multiplier gain.

W is the product output.

Z is a summing input.

All the variables and the scaling factor have the dimension of volts.

In the past, analog multipliers, such as the AD835, were

implemented almost exclusively with a Gilbert Cell topology

or a close derivative. The inherently asymmetric signal paths

for X and Y inevitably create amplitude and delay imbalances

between X and Y. In the ADL5391, the novel multiplier core

provides absolute symmetry between X and Y, minimizing

scaling and phasing differences inherent in the Gilbert Cell.

Calibration

The dc offset of the ADL5391 is approximately ±0 mV but

changes over temperature and has variation from part to part

(see Figure 4). It is generally not of concern unless the ADL5391

is operated down to dc (close to the point X = 0 V or Y = 0 V),

where 0 V is expected on the output (W = 0 V). For example,

when the ADL5391 is used as a VGA and a large amount of

attenuation is needed, the maximum attenuation is determined

by the input dc offset.

The simplified block diagram of the ADL5391 shows a main

multiplier cell that receives inputs X and Y and a second

multiplier cell in the feedback path around an integrating

buffer. The inputs to this feedback multiplier are the difference

of the output signal and the summing input, W − Z, and the

internal scaling reference, U. At dc, the integrating buffer

ensures that the output of both multipliers is exactly 0, therefore

Applying the proper voltage on the Z input removes the W

offset. Calibration can be accomplished by making the appropriate

cross plots and adjusting the Z input to remove the offset.

(W − Z)xU = XY, or W = XY/U + Z

(±)

Additionally, gain scaling can be adjusted by applying a dc

voltage to the GADJ pin, as shown in Figure 5.

By using a feedback multiplier that is identical to the main

multiplier, the scaling is traced back solely to U, which is

an accurate reference generated on-chip. As is apparent in

Equation ±, noise, drift, or distortion that is common to both

multipliers is rejected to first-order because the feedback

BASIC CONNECTIONS

Multiplier Connections

The best ADL5391 performance is achieved when the X, Y, and

Z inputs and W output are driven differentially; however, they

can be driven single-ended. Single-ended-to-differential

transformations (or differential-to-single-ended transformations)

can be done using a balun or active components, such as the

AD8313, the AD813± (both with operation down to dc), or the

AD835± (for higher drive capability). If using the ADL5391

single-ended without ac coupling capacitors, the reference

voltage of ±.5 V needs to be taken into account. Voltages above

±.5 V are positive voltages and voltages below ±.5 V are negative

voltages. Care needs to be taken not to load the ADL5391 too

heavily, the maximum reference current available is 50 mA.

multiplier essentially compensates the impairments generated

in the main multiplier.

The scaling factor, U, is fixed by design to 1.1± V. However, the

multiplier gain, α, can be adjusted by driving the GADJ pin with

a voltage ranging from 0 V to ± V. If left floating, then α = 1 or

0 dB, and the overall scaling is simply U = 1 V. For VGADJ = 0 V,

the gain is lowered by approximately 4 dB; for VGADJ = ± V,

the gain is raised by approximately 6 dB. Figure 5 shows the

relationship between α(V/V) and VGADJ.

Rev. 0 | Page 10 of 16

ADL5391

The dc component of the output is related to the square of both

the offset (OFST) and the signal input amplitude (E). The offset

can be found in Figure 4 and is approximately ±0 mV. The

second harmonic output grows with the square of the input

amplitude, and the signal bleedthrough grows proportionally

with the input signal. For smaller signal amplitudes, the signal

bleedthrough can be higher than the second harmonic

component. As the input amplitude increases, the second

harmonic component grows much faster than the signal

bleedthrough and becomes the dominant signal at the output.

If the X and Y inputs are driven too hard, third harmonic

components will also increase.

Matching the Input/Output

The input and output impedance’s of the ADL5391 change over

frequency, making it difficult to match over a broad frequency

range (see Figure 15 and Figure 16). The evaluation board is

matched for lower frequency operation, and the impedance

change at higher frequencies causes the change in gain seen in

Figure 6. If desired, the user of the ADL5391 can design a

matching network to fit their application.

Wideband Voltage-Controlled Amplifier/Amplitude

Modulator

Most of the data for the ADL5391 was collected by using it as a

fast reacting analog VGA. Either X or Y inputs can be used for

the RF input (and the other as the very fast analog control),

because either input can be used from dc to ± GHz. There is a

linear relationship between the analog control and the output of

the multiplier in the VGA mode. Figure 6 and Figure 7 show the

dynamic range available in VGA mode (without optimizing the

dc offsets).

For best performance creating harmonics, the ADL5391 should

be driven differentially. Figure 17 shows the performance of the

ADL5391 when used as a harmonic generator (the evaluation

board was used with R9 and R10 removed and R± = 56.± Ω). If

dc operation is necessary, the ADL5391 can be driven single

ended (without the dc blocks). The flatness of the response over

a broad frequency range depends on the input/output match.

The fundamental bleed through not only depends on the

amount of power put into the device but also depends on

matching the unused differential input/output to the same

impedance as the used input/output. Figure 18 shows the

performance of the ADL5391 when driven single ended

(without ac coupling capacitors), and Figure 19 shows the

schematic of the setup. A resistive input/output match were

used to match the input from dc to 1 GHz and the output from

dc to ± GHz. Reactive matching can be used for more narrow

frequency ranges. When matching the input/output of the

ADL5391, care needs to be taken not to load the ADL5391 too

heavily; the maximum reference current available is 50 mA.

The speed of the ADL5391 in VGA mode allows it to be used as

an amplitude modulator. Either or both inputs can have

modulation or CW applied. AM modulation is achieved by

feeding CW into X (or Y) and adding AM modulation to the Y

(or X) input.

Squaring and Frequency Doubling

Amplitude domain squaring of an input signal, E, is achieved

simply by connecting the X and Y inputs in parallel to produce

an output of E^±. The input can be single-ended, differential, or

through a balun (frequency range and dynamic range can be

limited if used single ended).

–15

When the input is a sine wave Esin(ωt), a signal squarer behaves

as a frequency doubler, because

–20

SECOND HARMONIC GAIN

–25

E²

±

[

Esin(ωt) ^±

]

=

(1−cos

(

±ωt

)

(3)

–30

–35

BLEEDTHRU GAIN

Ideally, when used for squaring and frequency doubling, there is

no component of the original signals on the output. Because of

internal offsets, this is not the case. If Equation 3 were rewritten

to include theses offsets, it could separate into three output

terms (Equation 4).

–40

–45

–50

–55

THIRD HARMONIC GAIN

–60

–65

[

Esin(ωt)+ OFST

]

×

[

Esin(ωt)+OFST =

]

E^±

±

(4)

⎛

⎞

±

10 100 200 300 400 500 600 700 800 900 1000

FREQUENCY (MHz)

⎜

⎟

[

cos(±ωt)

]

+±Esin(ωt)OFST + OFST +

⎜

±

⎝

⎠

Figure 17. ADL5391 Used as a Harmonic Generator

where:

The dc component is OFST^±+ E^±/±.

The input signal bleedthrough is ±Esin(ωt)OFST.

The input squared is E^±/±[cos(±ωt)].

Rev. 0 | Page 11 of 16

ADL5391

0

–5

be removed through calibration. Figure ±0 shows the response

of the ADL5391 as a square law detector, Figure ±1 shows the

error vs. the input power, and Figure ±± shows the

configuration used.

BLEEDTHRU GAIN

–10

–15

–20

–25

–30

–35

–40

–45

–50

–55

–60

–65

SECOND HARMONIC GAIN

0.7

0.6

0.5

0.4

0.3

0.2

0.1

0

THIRD HARMONIC GAIN

10 100 200 300 400 500 600 700 800 900 1000

FREQUENCY (MHz)

Figure 18. Single-Ended (DC) ADL5391 Used as a Harmonic Generator

53Ω

XM

XP

YM

10dB PAD

5dB PAD

150Ω

21Ω

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

XIN

WP

WM

2

V

(V rms)

IN

62Ω

74Ω

Figure 20. ADL5391 Used as Square Law Detector DC Output vs. Square of Input

53Ω YIN

21Ω

200Ω

YP

1.6

1.4

1.2

1.0

0.8

0.6

0.4

0.2

0

74Ω

5dB PAD

Figure 19. Setup for Single-Ended Data

Use as a Detector

The ADL5391 can be used as a square law detector. When

amplitude squaring is performed, there are components of the

multiplier output that correlate to the signal bleedthrough and

second harmonic, as seen in Equation 4. However, as noted in

the Squaring and Frequency Doubling section, there is also a dc

component that is directly related to the offset and the squared

input magnitude. If a signal is split and feed into the X and Y

inputs and a low-pass filter were place on the output, the resulting

dc signal would be directly related to the square of the input

magnitude. The intercept of the response will shift slightly from

part to part (and over temperature) with the offset, but this can

–0.2

–30

–25

–20

–15

–10

–5

0

5

10

PIN X (dBm)

Figure 21. ADL5391Used as a Square Law Detector Error vs. Power Input

C7

0.1µF

J6

11

12

XM

XP

YP

R2

T3

T2

TC1-1-13M

R6

24.9Ω

56.2Ω

T1

74µH

J2

WM

6

5

C18

WP

40µH

0.1µF

R4

100Ω

R12

OPEN

45nF

40nF

74µH

C4

0.1µF

J1

WP

WM

R5

24.9Ω

J8

XP

YM

YP

13

14

R1

56.2Ω

C20

0.1µF

Figure 22. Schematic for ADL5391 Used as Square Law Detector

Rev. 0 | Page 12 of 16

ADL5391

EVALUATION BOARD

C16

OPEN

C15

OPEN

R14

0Ω

R10

0Ω

YP_DC

TP6

ZP_DC

TP5

C7

0.1µF

C8

0.1µF

ZP

J5

YP

J6

R3

OPEN

R2

OPEN

C9

OPEN

C6

OPEN

T3

T4

TC1-1-13M

ZM

J4

YM

J7

C17

0.1µF

C18

YM_DC

TP7

ZM_DC

TP4

0.1µF

C19

R9

0Ω

R15

0Ω

R18

OPEN

R16

OPEN

11

12

10

9

0Ω

XP_DC

TP8

GADJ_DC

C4

0.1µF

R19

0Ω

ZPLS

ZMNS

YPLS

YMNS

13 XPLS

TP3

GADJ

J3

XP

J8

8

GADJ

R11

OPEN

R1

56.2Ω

C1

OPEN

T2

TC1-1-13M

C14

R13

XM

J9

0.1µF

14

15

16

7

6

5

XMNS

OPEN

COMM

WMNS

WPLS

R17

WM_DC

TP2

C5

OPEN

R6

24.9Ω

OPEN

XM_DC

TP9

ADL5391

C20

0.1µF

WM

J2

ENBL

R8

OPEN

ENBL

J10

R12

OPEN

R4

100Ω

C2

0.1µF

VMID

TP11

T1

TC1-1-13M

WP

J1

R20

0Ω

VMID

R5

24.9Ω

C13

OPEN

WP_DC

TP1

C3

VPOS VPOS

COMM

ENBL_DC

TP10

VPOS

2

0.1µF

R7

OPEN

3

1

4

2

SW1

1

3

C10

100pF

C12

0.1µF

TP

COMM

TP14

COMM

TP12

C11

4.7µF

VPOS

TP13

Figure 23. ADL5391-EVALZ Evaluation Board Schematic

Figure 25. Component Side Silkscreen of Evaluation Board

Figure 24. Component Side Metal of Evaluation Board

Rev. 0 | Page 13 of 16

ADL5391

Table 4. Evaluation Board Configuration Options

Component

Function

Part Number

Default Value

J1, J5, J6, J8

SMA connectors for single-ended, high frequency operation. If J5

and J6 are used, R9, R10, R14, and R15 should be removed. R2 and

R3 should also be populated to match the inputs. If used in broadband

operation, C4, C7, C8, and C2 need to be replaced with 0 Ω resistors.

WP, ZP, YP, XP

J2, J4, J7, J9

SMA connectors for broadband differential operation. If these are

used, baluns should be removed and jumped over using 0 Ω

resistors, and C14, C15, C18, and C20 should be removed.

WM, ZM, YM, XM

GADJ

J3

SMA connector for connection to GADJ.

T1, T2, T3, T4

Single-ended-to-differential transformation for high frequency ac

operation. If dc operation is necessary, the baluns can be removed

and jumped over using 0 Ω resistors.

TC1-1-13M+

Mini-Circuits

T3 and T4 are populated,

but the Y and Z inputs

are set up for dc operation.

C2, C4, C7, C8, C14,

C17, C18, C20

DC block capacitors.

0.1 μF, 0402 capacitors

C1, C5, C6, C9, C13,

C15, C16, C19

Not installed, dc block capacitors.

Open, 0402 capacitors

R9, R10, R14, R15, R18 Snubbing resistors.

0 Ω, 0402 resistors

R19, R20

R7, R13, R16, R17

C10

C12

C3

C11

R1

Snubbing resistors.

Filter capacitor.

Matching resistor.

0 Ω, 0603 resistors

Open, 0402 resistors

100 pF, 0402 capacitor

0.1 μF, 0402 capacitor

0.1 μF, 0603 capacitor

4.7 μF, 3216 capacitor

56.2 Ω, 0603 resistor

Open, 0603 resistors

R2, R3, R12

Matching resistors. Input impedance to X, Y, and Z inputs are the

same. For the same frequency, R1, R2, and R3 should be the same.

R5, R6

R4

R8, R11

SW1

TP1, TP2, TP4, TP5,

TP6, TP7, TP8, TP9

Matching resistor.s

Matching resistor.

Can be used for voltage divider or filtering.

Enable switch: enable = 5 V, disable = 0 V.

Green test loop.

24.9 Ω, 0402 resistors

100 Ω, 0603 resistor

Open, 0603 resistors

SW1 installed

WP_DC, WM_DC,

ZM_DC, ZP_DC, YP_DC,

YM_DC, XP_DC, XM_DC

TP13

Red test loop.

Black test loops.

Yellow test loops.

ADL5391.

V_POS

COMM

GADJ_DC, ENBL_DC, VMID

TP12, TP14

TP3, TP10, TP11

DUT

ADL5391ACPZ

Rev. 0 | Page 14 of 16

ADL5391

OUTLINE DIMENSIONS

0.50

0.40

0.30

3.00

BSC SQ

0.60 MAX

PIN 1

INDICATOR

*

1.65

13

12

16

1

0.45

1.50 SQ

1.35

PIN 1

INDICATOR

2.75

BSC SQ

TOP

VIEW

EXPOSED

PAD

(BOTTOM VIEW)

4

9

8

5

0.50

BSC

0.25 MIN

1.50 REF

0.80 MAX

12° MAX

0.65 TYP

0.90

0.85

0.80

0.05 MAX

0.02 NOM

SEATING

PLANE

0.30

0.23

0.18

0.20 REF

*

COMPLIANT TO JEDEC STANDARDS MO-220-VEED-2

EXCEPT FOR EXPOSED PAD DIMENSION.

Figure 26. 16-Lead Lead Frame Chip Scale Package [LFCSP_VQ]

3 mm × 3 mm Body, Very Thin Quad

(CP-16-3)

Dimensions shown in millimeters

ORDERING GUIDE

Model

ADL5391ACPZ-R2¹

ADL5391ACPZ-R7¹

ADL5391ACPZ-WP¹

ADL5391-EVALZ¹

Temperature Range

−40°C to +85°C

Package Description

16-Lead LFCSP_VQ

Evaluation Board

Package Option

CP-16-3

Ordering Quantity

250

1,500

50

CP-16-3

1

¹Z = Pb-free part.

Rev. 0 | Page 15 of 16

ADL5391

NOTES

registered trademarks are the property of their respective owners.

D06059-0-7/06(0)

Rev. 0 | Page 16 of 16


型号：	ADL5391
厂家：	ADI
描述：	DC to 2.0 GHz Multiplier DC到2.0GHz的乘数
文件：	总16页 (文件大小：430K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

ADL5391 [ADI]

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