Active Receive Mixer

LF to 500 MHz

AD8342

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
registered trademarks are the property of their respective owners.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700

www.analog.com

Fax: 781.461.3113

FEATURES

Broadband RF port: LF to 500 MHz
Conversion gain: 3.7 dB
Noise figure: 12.2 dB
Input IP3: 22.7 dBm
Input P

1dB

: 8.3 dBm

LO drive: 0 dBm
Differential high impedance RF input port
Single-ended, 50 LO input port
Single-supply operation: 5 V @ 98 mA
Power-down mode
Exposed paddle LFCSP: 3 mm × 3 mm

APPLICATIONS

Cellular base station receivers
ISM receivers
Radio links
RF instrumentation

FUNCTIONAL BLOCK DIAGRAM

COMM

IFOP

IFOM

COMM

RFCM

RFIN

VPMX

VPDC PWDN

EXRB COMM

VPLO LOCM

LOIN

COMM

BIAS

AD8342

05352-001

Figure 1.

GENERAL DESCRIPTION

The AD8342 is a high performance, broadband active mixer.
It is well suited for demanding receive-channel applications
that require wide bandwidth on all ports and very low inter-
modulation distortion and noise figure.

The AD8342 provides a typical conversion gain of 3.7 dB with
an RF frequency of 238 MHz. The integrated LO driver presents
a 50 input impedance with a low LO drive level, helping to
minimize the external component count.

The differential high impedance broadband RF port allows for
easy interfacing to both active devices and passive filters. The
RF input accepts input signals as large as 1.6 V p-p or 8 dBm
(relative to 50 ) at P

1dB

The open-collector differential outputs provide excellent bal-
ance and can be used with a differential filter or IF amplifier,
such as the AD8369 or AD8351. These outputs can also be con-
verted to a single-ended signal through the use of a matching
network or a transformer (balun). When centered on the VPOS
supply voltage, the outputs may swing ±2 V differentially.

The AD8342 is fabricated on an Analog Devices proprietary,
high performance SiGe IC process. The AD8342 is available in a
16-lead LFCSP. It operates over a -40°C to +85°C temperature
range. An evaluation board is also available.

AD8342

Rev. 0 | Page 2 of 20

TABLE OF CONTENTS

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

AC Performance ............................................................................... 4

Spur Table .......................................................................................... 5

Absolute Maximum Ratings............................................................ 6

ESD Caution.................................................................................. 6

Pin Configuration and Function Descriptions............................. 7

Typical Performance Characteristics ............................................. 8

Circuit Description......................................................................... 14

AC Interfaces................................................................................... 15

IF Port .......................................................................................... 16

LO Considerations ..................................................................... 17

High IF Applications.................................................................. 18

Evaluation Board ............................................................................ 19

Outline Dimensions ....................................................................... 20

Ordering Guide .......................................................................... 20

REVISION HISTORY

4/05--Revision 0: Initial Version

AD8342

Rev. 0 | Page 3 of 20

SPECIFICATIONS

= 5 V, T

= 25°C, f

= 238 MHz, f

= 286 MHz, LO power = 0 dBm, Z

= 50 , R

BIAS

= 1.82 k, RF termination = 100 , IF termi-

nated into 100 through a 2:1 ratio balun, unless otherwise noted.

Table 1.

Parameter

Conditions

Min

Typ

Max

Unit

RF INPUT INTERFACE

Return Loss

Hi-Z input terminated with 100 off-chip resistor

Input Impedance

Frequency = 238 MHz (measured at RFIN with RFCM ac-
grounded)

1||0.4

k||pF

DC Bias Level

Internally generated; port must be ac-coupled

2.4

OUTPUT INTERFACE

Output Impedance

Differential impedance, frequency = 48 MHz

10||0.5

k||pF

DC Bias Voltage

Supplied externally

4.75

5.25

Power Range

Via a 2:1 impedance ratio transformer

dBm

LO INTERFACE

Return Loss

DC Bias Voltage

Internally generated; port must be ac-coupled

- 1.6

POWER-DOWN INTERFACE

PWDN Threshold

3.5

PWDN Response Time

Device enabled, IF output to 90% of its final level

0.4

µs

Device disabled, supply current <5 mA

µs

PWDN Input Bias Current

Device enabled

-80

µA

Device disabled

+100

µA

POWER SUPPLY

Positive Supply Voltage

4.75

5.25

Quiescent Current

VPDC

Supply current for bias cells

VPMX, IFOP, IFOM

Supply current for mixer, R

BIAS

= 1.82 k

VPLO

Supply current for LO limiting amplifier

Total Quiescent Current

= 5 V

113

Power-Down Current

Device disabled

500

µA

AD8342

Rev. 0 | Page 4 of 20

AC PERFORMANCE

= 5 V, T

= 25°C, LO power = 0 dBm, Z

= 50 , R

BIAS

= 1.82 k, RF termination 100 , IF terminated into 100 via a 2:1 ratio balun,

unless otherwise noted.

Table 2.

Parameter

Conditions

Min

Typ

Max

Unit

RF FREQUENCY RANGE

500

MHz

LO FREQUENCY RANGE

High side LO

850

MHz

IF FREQUENCY RANGE

350

MHz

CONVERSION GAIN

= 460 MHz, f

= 550 MHz, f

= 90 MHz

3.2

= 238 MHz, f

= 286 MHz, f

= 48 MHz

3.7

SSB NOISE FIGURE

= 460 MHz, f

= 550 MHz, f

= 90 MHz

12.5

= 238 MHz, f

= 286 MHz, f

= 48 MHz

12.2

INPUT THIRD-ORDER INTERCEPT

RF1

= 460 MHz, f

RF2

= 461 MHz, f

= 550 MHz,

IF1

= 90 MHz, f

IF2

= 89 MHz each RF tone -10 dBm

22.2

dBm

RF1

= 238 MHz, f

RF2

= 239 MHz, f

= 286MHz,

IF1

= 48MHz, f

IF2

= 47MHz each RF tone -10 dBm

22.7

dBm

INPUT SECOND-ORDER INTERCEPT f

RF1

= 460 MHz, f

RF2

= 410 MHz, f

= 550 MHz, f

IF1

= 90 MHz,

IF2

= 140 MHz

dBm

RF1

= 238 MHz, f

RF2

= 188 MHz, f

= 286 MHz, f

IF1

= 48MHz,

IF2

= 98 MHz

dBm

INPUT 1 dB COMPRESSION POINT

= 460 MHz, f

= 550 MHz, f

= 90 MHz

8.5

dBm

= 238 MHz, f

= 286 MHz, f

= 48 MHz

8.3

dBm

LO TO IF OUTPUT LEAKAGE

LO power = 0 dBm, f

= 286 MHz

-27

dBc

LO TO RF INPUT LEAKAGE

LO power = 0 dBm, f

= 286 MHz

-55

dBc

2× LO TO IF OUTPUT LEAKAGE

LO power = 0 dBm, f

= 238 MHz, f

= 286 MHz

IF terminated into 100 and measured with a differential probe

-47

dBm

RF TO IF OUTPUT LEAKAGE

RF power = -10 dBm, f

= 238 MHz, f

= 286 MHz

-32

dBc

IF/2 SPURIOUS

RF power = -10 dBm, f

= 238 MHz, f

= 286 MHz

-70

dBc

Frequency ranges are those that were extensively characterized; this device can operate over a wider range. See the H

section for details.

igh IF Applications

AD8342

Rev. 0 | Page 5 of 20

SPUR TABLE

= 5 V, T

= 25°C, RF and LO power = 0 dBm, f

= 238MHz, f

= 286MHz, Z

= 50 , R

BIAS

= 1.82 k, RF termination 100 ,

IF terminated into 100 via a 2:1 ratio balun.

Note: Measured using standard test board. Typical noise floor of measurement system = -100 dBm.

Table 3.

- mf

0 1 2 3 4 5 6 7 8 9 10

<-100

-25 -54 -28 -45 -35 -39 -36 -42 -57 -44 -42 -41 -46 -59

-39 3.5 -42 -6 -48 -16 -50 -28 -57 -37 -68 -45 -54 -37 -61

-52 -47 -51 -49 -54 -56 -56 -62 -62 -66 -71 -80 -80 -67 -79

-81 -57 -79 -61 -82 -61 -74 -69 -94 -85 -89 -86 -86 -90 -81

-78 -70 -80 -79 -80 -85 -87 -92 -93 -96 -95 <-100

-97 <-100

-95

-98 -79 -95 -87 -96 -94 -95 -88 -98 -94 <-100 <-100 <-100 <-100 <-100

6 <-100

<-100

-99

<-100

-96 <-100

<-100

<-100 <-100 <-100 <-100 <-100

<-100 <-100 <-100 <-100 -96

<-100 -98

<-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100

<-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 -97

<-100 <-100 <-100 <-100 <-100 <-100

<-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 -99

<-100 <-100 <-100

<-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 -99

<-100 <-100 <-100 <-100

<-100 <-100 <-100 <-100 <-100 <-100 <-100 -96

<-100 -97

<-100 -96

<-100 <-100 <-100

<-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 -99

<-100 -98

<-100 <-100 <-100 <-100

<-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 -97

<-100 -97

-99

<-100 <-100

<-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 -98 -98 <-100

<-100

<-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100 <-100

AD8342

Rev. 0 | Page 6 of 20

ABSOLUTE MAXIMUM RATINGS

Table 4.

Parameter

Rating

Supply Voltage, V

5.5 V

RF Input Level

12 dBm

LO Input Level

12 dBm

PWDN Pin

+ 0.5 V

IFOP, IFOM Bias Voltage

5.5 V

Minimum Resistor from EXRB to COMM

1.8 k

Internal Power Dissipation

650 mW

77°C/W

Maximum Junction Temperature

135°C

Operating Temperature Range

-40°C to +85°C

Storage Temperature Range

-65°C to +150°C

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 sec-
tion of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.

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.

AD8342

Rev. 0 | Page 7 of 20

PIN CONFIGURATION AND FUNCTION DESCRIPTIONS

05352-002

PIN 1
INDICATOR

VPLO

LOCM

LOIN

COMM

11 PWDN

12 VPDC

10 EXRB
9 COMM

I
F

I
N

TOP VIEW

(Not to Scale)

AD8342

Figure 2. 16-Lead LFCSP

Table 5. Pin Function Descriptions

Pin No.

Mnemonic

Function

VPLO

Positive Supply Voltage for the LO Buffer: 4.75 V to 5.25 V.

2 LOCM

AC Ground for Limiting LO Amplifier. Internally biased to Vs

- 1.6 V. AC-couple to ground.

3 LOIN

LO Input. Nominal input level 0 dBm. Input level range -10 dBm to +4 dBm (relative to 50 ). Internally
biased to Vs

- 1.6 V. AC-couple.

4, 5, 8, 9, 13

COMM

Device Common (DC Ground).

6, 7

IFOM, IFOP

Differential IF Outputs (Open Collectors). Each requires dc bias of 5.00 V (nominal).

10 EXRB

Mixer Bias Voltage. Connect resistor from EXRB to ground. Typical value of 1.82 k sets mixer current to
nominal value. Minimum resistor value from EXRB to ground = 1.8 k. Internally biased to 1.17 V.

PWDN

Connect to Ground for Normal Operation. Connect pin to V

for disable mode.

VPDC

Positive Supply Voltage for the DC Bias Cell: 4.75 V to 5.25 V.

RFCM

AC Ground for RF Input. Internally biased to 2.4 V. AC-couple to ground.

RFIN

RF Input. Internally biased to 2.4 V. Must be ac-coupled.

VPMX

Positive Supply Voltage for the Mixer: 4.75 V to 5.25 V.

AD8342

Rev. 0 | Page 8 of 20

TYPICAL PERFORMANCE CHARACTERISTICS

= 5 V, T

= 25°C, RF power = -10 dBm, LO power = 0 dBm, Z

= 50 , R

BIAS

= 1.82 k, RF termination 100 , IF terminated into

100 via a 2:1 ratio balun, unless otherwise noted.

05352-004

RF FREQUENCY (MHz)

GAIN (

IF = 10MHz

550

100

150

200

250

300

350

400

450

500

IF = 90MHz

IF = 48MHz

IF = 140MHz

Figure 3. Conversion Gain vs. RF Frequency

05352-025

LO LEVEL (dBm)

GAIN (

15

10

IF = 48MHz

IF = 90MHz

IF = 140MHz

IF = 10MHz

Figure 4. Gain vs. LO Level, RF Frequency = 238 MHz

5.0

05352-039

TEMPERATURE (

GAIN (

4.5

4.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

20

40

Figure 5. Gain vs. Temperature, f

= 238 MHz, f

= 286 MHz

05352-005

IF FREQUENCY (MHz)

GAIN (

100

150

200

250

300

350

RF = 238MHz

RF = 460MHz

Figure 6. Conversion Gain vs. IF Frequency

5.0

05352-026

VPOS (V)

GAIN (

4.5

4.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

4.75

5.25

4.85

4.95

5.05

5.15

Figure 7. Gain vs. Vpos, f

= 238 MHz, f

= 286 MHz

3.40

3.90

05352-054

CONVERSION GAIN (238MHz)

RCE

NTAGE

3.45 3.50 3.55 3.60 3.65 3.70 3.75 3.80 3.85

NORMAL

MEAN = 3.7

STD. DEV. = 0.06

CONVERSION GAIN

(238MHz) PERCENTAGE

Figure 8. Conversion Gain Distribution, f

= 238 MHz, f

= 286 MHz

AD8342

Rev. 0 | Page 9 of 20

550

05352-007

RF FREQUENCY (MHz)

INPUT IP3 (

Bm)

100

150

200

250

300

350

400

450

500

IF = 10MHz

IF = 140MHz

IF = 90MHz

IF = 48MHz

Figure 9. Input IP3 vs. RF Frequency

15

05352-027

LO LEVEL (dBm)

INPUT IP3 (

Bm)

13

11

IF = 10MHz

IF = 48MHz

IF = 90MHz

140MHz

Figure 10. Input IP3 vs. LO Level, f

RF1

= 238 MHz, f

RF2

= 239 MHz

05352-032

TEMPERATURE (

INPUT IP3 (

Bm)

20

40

Figure 11. Input IP3 vs. Temperature, f

RF1

= 238 MHz, f

RF2

= 239 MHz,

= 286 MHz

05352-008

IF FREQUENCY (MHz)

INPUT IP3 (

Bm)

350

100

150

200

250

300

RF = 460MHz

RF = 238MHz

Figure 12. Input IP3 vs. IF Frequency

05352-028

VPOS (V)

INPUT IP3 (

Bm)

4.75

5.25

4.80 4.85 4.90 4.95 5.00 5.05 5.10 5.15 5.20

Figure 13. Input IP3 vs. Vpos, f

= 238 MHz, f

RF2

= 239 MHz

LO Frequency = 286 MHz

20.6

05352-055

INPUT IP3 (238MHz)

RCE

NTAGE

21.0

21.4

21.8

22.2

22.6

23.0

23.4

23.8

24.2

NORMAL

MEAN = 22.7

STD. DEV. = 0.41

INPUT IP3

(238MHz) PERCENTAGE

Figure 14. Input IP3 Distribution, f

= 238 MHz, f

= 286 MHz

AD8342

Rev. 0 | Page 10 of 20

550

05352-013

RF FREQUENCY (MHz)

T P1dB

(

)

100

150

200

250

300

350

400

450

500

10MHz

140MHz

48MHz

90MHz

Figure 15. Input P1dB vs. RF Frequency

10.0

5.0

15

05352-038

LO LEVEL (dBm)

T P1dB

(

)

9.5

9.0

8.5

8.0

7.5

7.0

6.5

6.0

5.5

13

11

IF = 10MHz

IF = 48MHz

IF = 90MHz

IF = 140MHz

Figure 16. Input P1dB vs. LO Level, f

= 238 MHz

05352-033

TEMPERATURE (

T P1dB

(

)

20

40

Figure 17. Input P1dB vs. Temperature, f

= 238 MHz, f

= 286 MHz

05352-014

IF FREQUENCY (MHz)

T P1dB

(

)

100

150

200

250

300

350

RF = 460MHz

RF = 238MHz

Figure 18. Input P1dB vs. IF Frequency

05352-031

T P1dB

(

)

VPOS (V)

4.75

5.25

4.85

4.95

5.05

5.15

Figure 19. Input P1dB vs. Vpos, f

= 238 MHz,

= 286 MHz

8.00

05352-056

IP1dB (238MHz)

RCE

NTAGE

8.60

8.05 8.10 8.15 8.20 8.25 8.30 8.35 8.40 8.45 8.50 8.55

NORMAL

MEAN = 8.3

STD. DEV. = 0.07

IP1dB (238MHz)

PERCENTAGE

Figure 20. Input IP3 Distribution, f

= 238 MHz, f

= 286 MHz

AD8342

Rev. 0 | Page 11 of 20

100

550

05352-010

RF FREQUENCY (MHz)

INPUT IP2 (

Bm)

IF = 10MHz

IF = 140MHz

IF = 90MHz

IF = 48MHz

150

200

250

300

350

400

450

500

Figure 21. Input IP2 vs. RF Frequency (Second RF = R F - 50 MHz)

05352-029

INPUT IP2 (

Bm)

15

LO LEVEL (dBm)

13

11

IF = 10MHz

IF = 48MHz

IF = 90MHz

IF = 140MHz

Figure 22. Input IP2 vs. LO Level, f

= 238 MHz, ,f

RF2

=188MHz

14.0

11.0

550

05352-

016

RF FREQUENCY (MHz)

NOISE F

I
GURE (d

13.5

13.0

12.5

12.0

11.5

100

150

200

250

300

350

400

450

500

Figure 23. Noise Figure vs. RF Frequency, IF Frequency = 48 MHz

05352-011

IF FREQUENCY (MHz)

INPUT IP2 (

Bm)

100

150

200

250

300

350

RF = 238MHz

RF = 460MHz

Figure 24. Input IP2 vs. IF Frequency (Second RF = R F - 50 MHz)

05352-030

INPUT IP2 (

Bm)

VPOS (V)

4.75

5.25

4.85

4.95

5.05

5.15

Figure 25. Input IP2 vs. Vpos, f

RF1

= 238 MHz,

RF2

= 188 MHz, f

= 286 MHz

05352-

017

IF FREQUENCY (MHz)

NOISE F

I
GURE (d

110

160

210

260

310

RF = 460MHz

RF = 238MHz

Figure 26. Noise Figure vs. IF Frequency

AD8342

Rev. 0 | Page 12 of 20

15

05352-018

LO POWER (dBm)

NF (dB)

13

11

NF = 10MHz

NF = 48MHz

NF = 90MHz

NF = 140MHz

Figure 27. Noise Figure vs. LO Power, f

= 238 MHz

5.0

1.8

05352-024

BIAS

)

GAIN (

4.5

4.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

Figure 28. Gain vs. R

BIAS

, RF Frequency = 238 MHz, LO Frequency = 286MHz

1.8

05352-037

BIAS

)

INPUT IP2 (

Bm)

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

Figure 29. Input IP2 vs. R

BIAS

, f

= 238 MHz (Second RF = RF 50MHz),

= 286 MHz

11.8

12.8

05352-023

NOISE FIGURE (dB)

RCE

NTAGE

11.9 12.0 12.1 12.2 12.3 12.4 12.5 12.6 12.7

NORMAL

MEAN = 12.25

STD. DEV. = 0.14

NF PERCENTAGE

Figure 30. Noise Figure Distribution, f

= 238 MHz, f

= 286 MHz

1.8

3.0

05352-015

BIAS

)

NOIS

FIGURE

AND INP

T IP

(dBm)

2.0

2.2

2.4

2.6

2.8

105

100

CURRE

NT (mA)

INPUT IP3

NOISE FIGURE

CURRENT

Figure 31. Noise Figure, Input IP3 and Supply Current vs. R

BIAS

RF1

= 238 MHz, f

RF2

= 239 MHz, f

= 286 MHz

1.8

05352-036

BIAS

)

T P1dB

(

)

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

Figure 32. Input P1dB vs. R

BIAS

, f

= 238 MHz, f

= 286 MHz

AD8342

Rev. 0 | Page 13 of 20

90

05352-021

LO FREQUENCY (MHz)

AKAGE

(dBc

)

10

20

30

40

50

60

70

80

250

450

650

850

Figure 33. LO to RF Leakage vs. LO Frequency, LO Power = 0 dBm

45

550

05352-035

RF FREQUENCY (MHz)

THROUGH (dBc

)

10

15

20

25

30

35

40

100

150

200

250

300

350

400

450

500

IF = 10MHz

IF = 48MHz

Figure 34. RF to IF Feedthrough, RF Power =

-10 dBm

45

850

05352-020

LO FREQUENCY (MHz)

THROUGH (dBc

)

10

15

20

25

30

35

40

150

250

350

450

550

650

750

Figure 35. LO to IF Feedthrough vs. LO Frequency, LO Power = 0 dBm

120

05352-034

TEMPERATURE (

CURRE

NT (mA)

20

40

100

Figure 36. Supply Current vs. Temperature

18

860

05352-059

LO FREQUENCY (MHz)

TURN LOS

(dB)

10

12

14

16

160

260

360

460

560

660

760

Figure 37. LO Return Loss vs. LO Frequency

COMM

IFOP

IFOM

COMM

RFCM

RFIN

VPMX

VPDC

PWDN

EXRB

COMM

VPLO

LOCM

LOIN

COMM

AD8342

RF IN

1nF

100pF

0.1

100pF

0.1

VPOS

1nF

LO IN

TC2-1T

IF OUT

(50

)

100pF

0.1

VPOS

1nF

100

1.82k

100pF

VPOS

100pF

0.1

05352-058

Figure 38. Characterization Circuit Used to Measure TPC Data

AD8342

Rev. 0 | Page 14 of 20

CIRCUIT DESCRIPTION

The AD8342 is an active mixer optimized for operation within
the input frequency range of near dc to 500 MHz. It has a dif-
ferential, high impedance RF input that can be terminated or
matched externally. The RF input can be driven either single-
ended or differentially. The LO input is a single-ended 50
input. The IF outputs are differential open-collectors. The mixer
current can be adjusted by the value of an external resistor to
optimize performance for gain, compression, and intermodula-
tion, or for low power operation. Figure 39 shows the basic
blocks of the mixer, including the LO buffer, RF voltage-to-
current converter, bias cell, and mixing core.

The RF voltage to RF current conversion is done via a resistively
degenerated differential pair. To drive this port single-ended,
the RFCM pin should be ac-grounded while the RFIN pin is
ac-coupled to the signal source. The RF inputs can also be
driven differentially. The voltage-to-current converter then
drives the emitters of a four-transistor switching core. This
switching core is driven by an amplified version of the local
oscillator signal connected to the LO input. There are three
limiting gain stages between the external LO signal and the
switching core. The first stage converts the single-ended LO
drive to a well-balanced differential drive. The differential drive
then passes through two more gain stages, which ensures a lim-
ited signal drives the switching core. This affords the user a
lower LO drive requirement, while maintaining excellent distor-
tion and compression performance. The output signal of these
three LO gain stages drives the four transistors within the mixer
core to commutate at the rate of the local oscillator frequency.
The output of the mixer core is taken directly from its open
collectors. The open collector outputs present a high impedance
at the IF frequency. The conversion gain of the mixer depends
directly on the impedance presented to these open collectors. In
characterization, a 100 load was presented to the part via a
2:1 impedance transformer.

The device also features a power-down function. Application of
a logic low at the PWDN pin allows normal operation. A high
logic level at the PWDN pin shuts down the AD8342. Power
consumption when the part is disabled is less than 10 mW.

The bias for the mixer is set with an external resistor (R

BIAS

)

from the EXRB pin to ground. The value of this resistor directly
affects the dynamic range of the mixer. The external resistor
should not be lower than 1.82 k. Permanent damage to the
part could result if values below 1.8 k are used. This resistor
sets the dc current through the mixer core. The performance
effects of changing this resistor can be seen in the Typical Per-
formance Characteristics section.

05352-040

INPUT

VPLO

IFOP

IFOM

RFIN

RFCM

BIAS

EXTERNAL

BIAS

RESISTOR

VPDC

PWDN

Figure 39. Simplified Schematic Showing the Key Elements of the AD8342

As shown in Figure 40, the IF output pins, IFOP and IFOM, are
directly connected to the open collectors of the NPN transistors
in the mixer core so the differential and single-ended imped-
ances looking into this port are relatively high--on the order of
several k. A connection between the supply voltage and these
output pins is required for proper mixer core operation.

05352-041

IFOP IFOM

LOIN

RFCM

RFIN

COMM

Figure 40. AD8342 Simplified Schematic

The AD8342 has three pins for the supply voltage: VPDC,
VPMX, and VPLO. These pins are separated to minimize or
eliminate possible parasitic coupling paths within the AD8342
that could cause spurious signals or reduced interport isolation.
Consequently, each of these pins should be well bypassed and
decoupled as close to the AD8342 as possible.

AD8342

Rev. 0 | Page 15 of 20

AC INTERFACES

The AD8342 is designed to downconvert radio frequencies (RF)
to lower intermediate frequencies (IF) using a high or low-side
local oscillator (LO). The LO is injected into the mixer core at a
frequency higher or lower than the desired input RF. The
difference between the LO and the RF , f

- f

RF,

(high side) or

- f

(low side) is the intermediate frequency, f

. In addition

to the desired RF signal, an RF image is downconverted to the
desired IF frequency. The image frequency is at f

+ f

when

driven with a high side LO . When using a broadband load, the
conversion gain of the AD8342 is nearly constant over the
specified RF input band (see Figure 3).

The AD8342 is designed to operate over a broad frequency
range. It is essential to ac-couple RF and LO ports to prevent dc
offsets from skewing the mixer core in an asymmetrical man-
ner, potentially degrading noise figure and linearity.

The RF input of the AD8342 is high impedance, 1 k across the
frequency range shown in Figure 41. The input capacitance
decreases with frequency due to package parasitics.

2.00

1.00

05352-042

FREQUENCY (Hz)

I
S

ANCE

)

CAP

ACITANCE

(pF)

1.75

1.50

0.75

1.25

1.00

0.50

0.75

0.50

0.25

100M 200M 300M 400M 500M 600M 700M 800M 900M

Figure 41. RF Input Impedance

The matching or termination used at the RF input of the
AD8342 has a direct effect on its dynamic range. The charac-
terization circuit, as well as the evaluation board, uses a 100
resistor to terminate the RF port. This termination resistor in
shunt with the input stage results in a return loss of better than
-10 dBm (relative to 50 ). Table 4 shows gain, IP3, P1dB, and
noise figure for four different input networks. This data was
measured at an RF frequency of 250 MHz and at an LO
frequency of 300 MHz.

Table 4. Dynamic Performance for Various Input Networks

Input
Network

50
Shunt

100
Shunt

500
Shunt

Matched
(Fig. 40)

Gain (dB)

0.66

3.5

5.3

9.3

IIP3

(dBm)

25.4 22.9 20.

18.5

P1dB (dBm)

10.8

8.4

6.3

2.3

NF (dB)

12.5

10.2

10.5

The RF port can also be matched using an LC circuit, as shown
in Figure 42.

05352-043

= 50

MAIN

= 250MHz

3.6pF

100nH

(1000 + j0)

Figure 42. Matching Circuit

Impedance transformations of greater than 10:1 result in a
higher Q circuit and thus a narrow RF input bandwidth. A 1 k
resistor is placed across the RF input of the device in parallel
with the device internal input impedance, creating a 500 load.
This impedance is matched to as close as possible to 50 for
the source, with standard components using a shunt C, series L
matching circuit (see Figure 43).

05352-044

25.0

10.0

25.0

50.0

100.0

200.0

500.0

200.0

100.0

50.0

Q = 3.0

Point 1(1000.0 + j0.0) Q = 0.0 at 250.000 MHz

Point 2(500.0 + j0.0) Q = 0.0 at 250.000 MHz

Point 3(55.6 - j157.2) Q = 2.8 at 250.000 MHz

Point 4(55.6 - j0.1) Q = 0.0 at 250.000 MHz

Figure 43. LC Matching Example

AD8342

Rev. 0 | Page 16 of 20

IF PORT

The IF port comprises open-collector differential outputs. The
NPN open collectors can be modeled as current sources that are
shunted with resistances of ~10 k in parallel with capacitances
of ~1 pF.

The specified performance numbers for the AD8342 were
measured with 100 differential terminations. However, dif-
ferent load impedances may be used where circumstances dic-
tate. In general, lower load impedances result in lower conver-
sion gain and lower output P1dB. Higher load impedances
result in higher conversion gain for small signals, but lower IP3
values for both input and output.

If the IF signal is to be delivered to a remote load, more than a
few millimeters away at high output frequencies, avoid unin-
tended parasitic effects due to the intervening PCB traces. One
approach is to use an impedance transforming network or
transformer located close to the AD8342. If very wideband out-
put is desired, a nearby buffer amplifier may be a better choice,
especially if IF response to dc is required. An example of such a
circuit is presented in Figure 45, in which the AD8351 differen-
tial amplifier is used to drive a pair of 75 transmission lines.
The gain of the buffer can be independently set by appropriate
choice of the value for the gain resistor, R

0.5

05352-045

FREQUENCY (Hz)

I
S

ANCE

)

CAP

ACITANCE

(pF)

0.4

0.3

0.2

0.1

0.2

100M 200M 300M 400M 500M 600M 700M 800M 900M

Figure 44. IF Port Impedance

05352-046

COMM

IFOP

IFOM

COMM

AD8342

AD8351

RFC

= 100

100

Tx LINE Z

= 75

Tx LINE Z

= 75

Figure 45. AD8351 Used as Transmission Line Driver and Impedance Buffer

The high input impedance of the AD8351 allows for a shunt
differential termination to provide the desired 100 load to the
AD8342 IF output port.

It is necessary to bias the open-collector outputs using one of
the schemes presented in Figure 47 and Figure 48. Figure 47
illustrates the application of a center tapped impedance trans-
former. The turns ratio of the transformer should be selected to
provide the desired impedance transformation. In the case of a
50 load impedance, a 2-to-1 impedance ratio transformer
should be used to transform the 50 load into a 100 differ-
ential load at the IF output pins. Figure 48 illustrates a differen-
tial IF interface where pull-up choke inductors are used to bias
the open-collector outputs. The shunting impedance of the
choke inductors used to couple dc current into the mixer core
should be large enough at the IF operating frequency so it does
not load down the output current before reaching the intended
load. Additionally, the dc current handling capability of the
selected choke inductors needs to be at least 45 mA. The self-
resonant frequency of the selected choke should be higher than
the intended IF frequency. A variety of suitable choke inductors
are commercially available from manufacturers such as Murata
and Coilcraft. Figure 46 shows the loading effects when using
nonideal inductors. An impedance transforming network may
be required to transform the final load impedance to 100 at
the IF outputs. There are several good reference books that
explain general impedance matching procedures, including:

Chris Bowick, RF Circuit Design, Newnes, Reprint Edition,
1997.

David M. Pozar, Microwave Engineering, Wiley Text Books,
Second Edition, 1997.

Guillermo Gonzalez, Microwave Transistor Amplifiers:
Analysis and Design, Prentice Hall, Second Edition, 1996.

05352-049

180

330

50MHz

500MHz

270

300

120

240

150

210

REAL

CHOKES

IDEAL

CHOKES

Figure 46. IF Port Loading Effects Due to Finite Q Pull-Up Inductors

(Murata BLM18HD601SN1D Chokes)

AD8342

Rev. 0 | Page 17 of 20

05352-047

COMM

IFOP

IFOM

COMM

AD8342

= 100

IF OUT
Z

= 50

2:1

Figure 47. Biasing the IF Port Open-Collector Outputs

Using a Center-Tapped Impedance Transformer

05352-048

COMM

IFOP

IFOM

COMM

AD8342

RFC

= 100

IF OUT+

IF OUT

IMPEDANCE

TRANSFORMING

NETWORK

Figure 48. Biasing the IF Port Open-Collector Outputs

Using Pull-Up Choke Inductors

The AD8342 is optimized for driving a 100 load. Although
the device is capable of driving a wide variety of loads, to main-
tain optimum distortion and noise performance, it is advised
that the presented load at the IF outputs is close to 100 . The
linear differential voltage conversion gain of the mixer can be
modeled as

LOAD

where:

LOAD

is the single-ended load impedance.

is the transistor transconductance and is equal to

1810/R

BIAS

is 15 .

The external R

BIAS

resistor is used to control the power dissipa-

tion and dynamic range of the AD8342. Because the AD8342
has internal resistive degeneration, the conversion gain is pri-
marily determined by the load impedance and the on-chip
degeneration resistors. Figure 49 shows how gain varies with IF
load. The external R

BIAS

resistor has only a small effect. The

most direct way to affect conversion gain is by varying the load
impedance. Small loads result in lower gains while larger loads
increase the conversion gain. If the IF load impedance is too
large it causes a decrease in linearity (P1dB, IP3). In order to
maintain positive conversion gain and preserve SFDR perform-
ance, the differential load presented at the IF port should
remain in the range of ~ 100 to 250 .

1000

05352-057

IF LOAD (

)

VOLTAGE GAIN (

100

MEASURED

MODELED

Figure 49. Voltage Conversion Gain vs. IF Loading

LO CONSIDERATIONS

The LOIN port provides a 50 load impedance with common-
mode decoupling on LOCM. Again, common-grade ceramic
capacitors provide sufficient signal coupling and bypassing of
the LO interface.

The LO signal needs to have adequate phase noise characteris-
tics and low second-harmonic content to prevent degradation
of the noise figure performance of the AD8342. An LO plagued
with poor phase noise can result in reciprocal mixing, a mecha-
nism that causes spectral spreading of the downconverted sig-
nal, limiting the sensitivity of the mixer at frequencies close-in
to any large input signals. The internal LO buffer provides
enough gain to hard-limit the input LO and provide fast switch-
ing of the mixer core. Odd harmonic content present on the LO
drive signal should not impact mixer performance; however,
even-order harmonics cause the mixer core to commutate in an
unbalanced manner, potentially degrading noise performance.
Simple lumped element low-pass filtering can be applied to help
reject the harmonic content of a given local oscillator, as shown
in Figure 50. The filter depicted is a common 3-pole Chebyshev,
designed to maintain a 1-to-1 source-to-load impedance ratio
with no more than 0.5 dB of ripple in the pass band. Other filter
structures can be effective as long as the second harmonic of the
LO is filtered to negligible levels, for example, ~30 dB below the
fundamental.

05352-050

AD8342

LOIN

COMM

LOCM

FOR R

= R

- FILTER CUTOFF FREQUENCY

SOURCE

C1 =

1.864

C3 =

1.834

L2 =

1.28R

Figure 50. Using a Low-Pass Filter to Reduce LO Second Harmonic

AD8342

Rev. 0 | Page 18 of 20

HIGH IF APPLICATIONS

In some applications it may be desirable to use the AD8342 as
an up-converting mixer. The AD8342 is a broadband mixer
capable of both up and down conversion. Unlike other mixers
that rely on on-chip reactive circuitry to optimize performance
over a specific band, the AD8342 is a versatile general-purpose
device that can be used from arbitrarily low frequencies to sev-
eral GHz. In general, the following considerations help to en-
sure optimum performance:

Minimize ac loading impedance of IF port bias network.

Maximize power transfer to the desired ac load.

For maximum conversion gain and the lowest noise per-
formance reactively match the input as described in the
IF Port section.

For maximum input compression point and input intercept

points resistively terminate the input as described in the
IF Port section.

As an example, Figure 51 shows the AD8342 as an up-
converting mixer for a WCDMA single-carrier transmitter de-
sign. For this application, it was desirable to achieve -65 dBc
adjacent channel power ratio (ACPR) at a -13 dBm output
power level. The ACPR is a measure of both distortion and
noise carried into an adjacent frequency channel due to the
finite intercept points and noise figure of an active device.

COMM

IFOP

IFOM

COMM

RFCM

RFIN

VPMX

VPDC

PWDN

EXRB

COMM

VPLO

LOCM

LOIN

COMM

AD8342

05352-

052

VPOS

34nH

100pF

1nF

ETC1-1-13

100pF

0.1

VPOS

1nF

1970MHz

OSC

1.82k

100pF

4.7pF

170MHz

INPUT

100nH

1nF

499

VPOS

100pF

0.1pF

2140MHz OUT

1nF

Figure 51. WCDMA Tx Up-Conversion Application Circuit

Because a WCDMA channel encompasses a bandwidth of
almost 5 MHz, it is necessary to keep the Q of the matching
circuit low enough so that phase and magnitude variations are
below an acceptable level over the 5 MHz band. It is possible
to use purely reactive matching to transform a 50 source
to match the raw ~1 k input impedance of the AD8342.
However, the L and C component variations could present

production concerns due to the sensitivity of the match. For
this application, it is advantageous to shunt down the ~1 k
input impedance using an external shunt termination resistor
to allow for a lower Q reactive matching network. The input is
terminated across the RFIN and RFCM pins using a 499
termination. The termination should be as close to the device as
possible to minimize standing wave concerns. The RFCM is
bypassed to ground using a 1 nF capacitor. A dc blocking ca-
pacitor of 1 nF is used to isolate the dc input voltage present on
the RFIN pin from the source. A step-up impedance transfor-
mation is realized using a series L shunt C reactive network.
The actual values used need to accommodate for the series L
and stray C parasitics of the connecting transmission line seg-
ments. When using the customer evaluation board with the
components specified in Figure 51, the return loss over a 5 MHz
band centered at 170 MHz was better than 10 dB.

External pull-up choke inductors are used to feed dc bias into
the open-collector outputs. It is desirable to select pull-up choke
inductors that present high loading reactance at the output
frequency. Coilcraft 0302CS series inductors were selected due
to their very high self-resonant frequency and Q. A 1:1 balun
was ac-coupled to the output to convert the differential output
to a single-ended signal and present the output with a 50
ac loading impedance.

The performance of the circuit is shown in Figure 52. The aver-
age ACPR of the adjacent and alternate channels is presented
vs. output power. The circuit provides a 65 dBc ACPR at
-13 dBm output power. The optimum ACPR power level can be
shifted to the right or left by adjusting the output loading and
the loss of the input match.

60

70

25

05352-

053

OUTPUT POWER (dBm)

ACPR (dBc)

62

64

66

68

20

15

10

ADJACENT

CHANNELS

ALTERNATE

CHANNELS

Figure 52. Single Carrier WCDMA ACPR Performance of Tx Up-Conversion

Circuit (Test Model 1_64)

AD8342

Rev. 0 | Page 19 of 20

EVALUATION BOARD

An evaluation board is available for the AD8342. The evaluation board is configured for single-ended signaling at the IF output port via a
balun transformer. The schematic for the evaluation board is presented in Figure 53.

1000pF

0.1

VPOS

RF_IN

1000pF

INLO

1000pF

0.1

C10

100pF

VPOS

R11

R16

R10

R12

OPEN

TC2-1T

OPEN

100

TRACES,

NO GROUND PLANE

IF_OUT+

IF_OUT

R15

OPEN

100

C14

OPEN

COMM

IFOP

IFOM

COMM

RFCM

RFIN

VPMX

VPDC PWDN EXRB COMM

VPLO LOCM LOIN COMM

DUT

1.82k

C11

100pF

C13

100pF

C12

0.1

VPOS

GND

PWDN

VPOS

10k

PWDN

05352-003

TRACE

Figure 53. Evaluation Board

Table 6. Evaluation Board Configuration Options

Component

Function

Default Conditions

R1, R2, R7,
C2, C4, C5, C6, C10
C12, C13, C14, C9

Supply decoupling. Shorts or power supply decoupling resistors and filter
capacitors.

R1, R2, R7 = 0
C4, C6 = 1000 pF
C10, C13 = 100 pF
C2, C5, C12, C9 = 0.1 µF

R3, R4

Options for single-ended IF output circuit.

R3, R4 = Open

R15, 16

R15, R16 = 0

R6, C11

BIAS

resistor that sets the bias current for the mixer core. The capacitor

provides ac bypass for R6.

R6 = 1.82 k
C11 = 100 pF

Pull down for the PWDN pin.

R8 = 10 k

Link to PWDN pin.

R9 = 0

C3, R5, C16, L1

RF input. C3 provides dc block for RF input. R5 provides a resistive input
termination. C16 and L1 are provided for reactive matching the input.

C3 = 1000 pF
R5 = 100
C14 = Open
L1 = 0

RF common ac coupling. Provides dc block for RF input common
connection.

C1 = 1000 pF

C8
C7

LO input ac coupling. Provides dc block for the LO input.
LO common ac coupling. Provides dc block for LO input common
connection.

C7, C8 = 1000 pF

Power down. The part is on when the PWDN is connected to ground via a
10 k resistor. The part is disabled when PWDN is connected to the positive
supply (V

) via W1.

T1, R12, R11, Z3,
Z4, Z1, Z2, R10

IF output interface. T1 converts a differential high impedance IF output to
single-ended. When loaded with 50 , this balun presents a 100 load to
the mixers collectors. The center tap of the primary is used to supply the
bias voltage (V

) to the IF output pins.

T1 = TC2-1T, 2:1 (Mini-Circuits)
R12 = Open
R10, R11 = 0
Z3, Z4 = Open
Z1, Z2 = Open

AD8342

Preliminary Technical Data

Rev. 0 | Page 20 of 20

OUTLINE DIMENSIONS

0.50

BSC

0.60 MAX

PIN 1

INDICATOR

1.50 REF

0.50
0.40
0.30

0.25 MIN

0.45

2.75

BSC SQ

TOP

VIEW

12° MAX

0.80 MAX
0.65 TYP

SEATING

PLANE

PIN 1

INDICATOR

0.90
0.85
0.80

0.30
0.23
0.18

0.05 MAX
0.02 NOM

0.20 REF

3.00

BSC SQ

*1.65

1.50 SQ
1.35

EXPOSED

PAD

(BOTTOM VIEW)

*COMPLIANT TO JEDEC STANDARDS MO-220-VEED-2

EXCEPT FOR EXPOSED PAD DIMENSION.

Figure 54. 16-Lead Lead Frame Chip Scale Package [LFCSP_VQ]

3 mm x 3 mm Body, Very Thin Quad

(CP-16-3)

Dimensions in millimeters

ORDERING GUIDE

Models

Temperature
Package

Package Description

Package
Outline

Branding

Transport Media,
Quanity

AD8342ACPZ-REEL7

-40°C to +85°C

16-Lead Lead Frame Chip Scale Package
[LFCSP_VQ]

CP-16-3

Q01

1,500, Reel

AD8342ACPZ-R2

-40°C to +85°C

16-Lead Lead Frame Chip Scale Package
[LFCSP_VQ]

CP-16-3

Q01

250, Reel

AD8342ACPZ-WP

-40°C to +85°C

16-Lead Lead Frame Chip Scale Package
[LFCSP_VQ]

CP-16-3

Q01

50, Waffle Pack

AD8342-EVAL

Evaluation Board

Z = Pb-free part.

regis-

tered trademarks are the property of their respective owners.

D0535204/05(0)

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