AVAGO AMMP-6232

AMMP-6232
18 to 32 GHz GaAs High Linearity LNA in SMT Package
Data Sheet
Description
Features
Avago’s AMMP-6232 is an easy-to-use broadband, high
gain, high linearity Low Noise Amplifier in a surface mount
package. The wide band and unconditionally stable
performance makes this MMIC ideal as a primary or subsequential low noise block or a transmitter driver. The MMIC
has 4 gain stages and requires a 4V, 138mA power supply
for optimal performance. Since this MMIC covers several
bands, it can reduce part inventory and increase volume
purchase options The MMIC is fabricated using PHEMT
technology. The surface mount package eliminates the
need of “chip & wire” assembly for lower cost. This MMIC is
fully SMT compatible with backside grounding and I/Os.
•
•
•
•
Pin Connections (Top View)
Applications
1
2
3
100pF
8
4
100pF
7
6
5
Topview
Packagebase:GND
Pin
1
2
3
4
5
6
7
8
Function
Vdd
RFout
Vg
RFin
Surface Mount Package, 5.0 x 5.0 x 1.25 mm
Single Power Supply Pin
Unconditionally Stable
50Ohm Input and Output Match
Specifications (Vdd = 4.0V, Idd = 138mA)
•
•
•
•
RF Frequencies: 18 - 32 GHz
High Output IP3: 29dBm
High Small-Signal Gain: 23dB
Typical Noise Figure: 3dB
•
•
•
•
Microwave Radio systems
Satellite VSAT, DBS Up/Down Link
LMDS & Pt-Pt mmW Long Haul
Broadband Wireless Access
(including 802.16 and 802.20 WiMax) • WLL and MMDS loops
• Commercial grade military
Note:
1. This MMIC uses depletion mode pHEMT devices.
2. Negative voltage is used for the gate bias
Attention:
Observe precautions for
handling electrostatic
sensitive devices.
ESD Machine Model (Class A)
ESD Human Body Model (Class 1A)
Refer to Avago Application Note A004R:
Electrostatic Discharge Damage and Control
Absolute Maximum Ratings [1]
Parameters / Conditions
Symbol
Unit
Max
Drain to Ground Voltage
Vdd
V
5.5
Gate-Drain Voltage
Vgd
V
-8
Drain Current
Idd
mA
200
Gate Bias Voltage
Vg
V
+0.8
Gate Bias Current
Ig
mA
1
RF CW Input Power Max
Pin
dBm
10
Max channel temperature
Tch
C
+150
Storage temperature
Tstg
C
-65 +150
Maximum Assembly Temp
Tmax
C
260 for 20s
1. Operation in excess of any of these conditions may result in permanent damage to this device. The absolute maximum ratings for Vdd, Vgd, Idd,
Vg, Ig and Pin were determined at an ambient temperature of 25°C unless noted otherwise.
DC Specifications/ Physical Properties [2]
Parameter and Test Condition
Symbol
Unit
Drain Supply Current (Vd=4.0 V)
Idd
mA
Drain Supply Voltage
Vd
V
Gate Bias Current
Ig
mA
Gate Bias Voltage
Vg
V
Thermal Resistance(3)
θjc
°C/W
Min
3
Typ
Max
135
150
4
5
0.1
-1.1
-0.95
-0.8
35.1
2. Ambient operational temperature TA=25°C unless noted
3. Channel-to-backside Thermal Resistance (Tchannel = 34°C) as measured using infrared microscopy. Thermal Resistance at
backside temp. (Tb) = 25°C calculated from measured data.
AMMP-6232 RF Specifications [4]
TA= 25°C, Vdd = 4.0 V, Idd =135 mA, Zo=50 W
Parameters and Test Conditions
Freq. (GHz)
Symbol
Units
Minimum
Typical
Small-Signal Gain[5]
20, 26, 29
Gain
dB
19
23
Noise Figure into 50W[5]
20, 26, 29
NF
dB
3
Output Power at 1dB Gain Compression
P-1dB
dBm
18
Output Power at 3dB Gain Compression
Psat
dBm
20
Output Third Order Intercept Point
OIP3
dBm
29
Isolation
Iso
dB
-45
Input Return Loss
RLin
dB
-10
Output Return Loss
RLout
dB
-10
4. Refer to characteristic plots for detailed individual frequency performance.
5. All tested parameters guaranteed with measurement accuracy ± 1.5dB for gain and ±0.4dB for NF.
Maximum
4.5
Sigma
AMMP-6232 Typical Performance [1], [2]
40
5
30
4
NoiseFigure (dB)
S21 (dB)
(TA = 25°C, Vdd=4V, Idd=138mA, Zin = Zout = 50 W unless noted)
20
10
0
15
20
25
30
3
2
1
0
35
18
20
22
Frequency (GHz)
28
30
32
Figure 2. Noise Figure
0
20
OP1dB (dBm)
-5
S11 (dB)
26
Frequency (GHz)
Figure 1. Small-signal Gain
-10
-15
-20
-25
15
20
25
30
15
10
5
0
35
18
Frequency (GHz)
20
22
24
26
28
30
32
30
32
Frequency (GHz)
Figure 3. Input Return Loss
Figure 4. Output P-1dB
0
30
-5
25
OIP3 (dBm)
S22 (dB)
24
-10
-15
-20
20
15
10
5
-25
15
20
25
30
35
18
20
24
26
28
Frequency (GHz)
Frequency (GHz)
Figure 5. Output Return Loss
22
Figure 6. Output IP3
Note:
1. S-parameters are measured on R&D Eval Board as shown in Figure 20. Effects of connectors and board traces are included in results.
2. Noise Figure is measured on R&D Eval Board as shown in Figure 20, and with a 3dB pad at the input. Board and Connector losses are already deembeded from the data.
AMMP-6232 Typical Performance (cont.)
S12 (dB)
(TA = 25°C, Vdd=4V, Idd=138mA, Zin = Zout = 50 W unless noted)
-20
200
-30
170
Idd (mA)
-40
-50
140
110
-60
80
-70
15
20
25
30
50
35
3
Frequency (GHz)
Figure 7. Isolation
NoiseFigure (dB)
S21 (dB)
4.5
5
5
30
20
4V
10
5V
3V
0
15
20
25
30
Frequency (GHz)
4
3
2
3V
4V
1
5V
0
18
35
-5
-5
-10
-10
S22 (dB)
0
4V
3V
-20
15
24
26
28
30
32
20
25
30
Frequency (GHz)
Figure 11. Input Return Loss Over Vdd
-15
4V
-20
5V
-25
5V
-25
22
Figure 10. Noise Figure over Vdd
0
-15
20
Frequency (GHz)
Figure 9. Gain over Vdd
S11 (dB)
4
Vdd (V)
Figure 8. Total Current
40
3.5
3V
-30
35
15
20
25
30
Frequency (GHz)
Figure 12. Output Return Loss Over Vdd
35
AMMP-6232 Typical Performance (cont.)
(TA = 25°C, Vdd=4V, Idd=138mA, Zin = Zout = 50 W unless noted)
35
30
20
OIP3 (dBm)
OP1dB (dBm)
25
15
3V
10
4V
25
20
22
24
26
28
30
5V
5
5
20
4V
10
5V
18
3V
15
18
32
20
22
Figure 13. Output P-1dB over Vdd
30
32
5
NoiseFigure (dB)
30
S21 (dB)
28
Figure 14. Output IP3 Over Vdd
40
20
25C
10
85C
-40C
0
15
20
25
30
Frequency (GHz)
4
3
2
-5
S22 (dB)
-10
25C
-40C
20
22
24
26
28
30
32
-10
-15
25C
-20
85C
-25
85C
15
20
Figure 16. Noise Figure over Temp
-5
-25
85C
Frequency (GHz)
0
-20
25C
18
35
0
-15
-40C
1
0
Figure 15. Gain over Temp
S11 (dB)
26
Frequency (GHz)
Frequency (GHz)
-40C
-30
25
30
Frequency (GHz)
Figure 17. Input Return Loss Over Temp
24
35
15
20
25
30
Frequency (GHz)
Figure 18. Output Return Loss Over Temp
35
AMMP-6232 Application and Usage
Biasing and Operation
The AMMP-6232 is normally biased with a positive drain
supply connected to the VDD pin and a negative gate
bias through bypass capacitors as shown in Figure 19. The
recommended drain supply voltage is 4 V and the gate bias
is approximately -0.95V to get the corresponding drain
current of 138mA. It is important to have 0.1uF bypass
capacitors and the capacitor should be placed as close
to the component as possible. Aspects of the amplifier
performance may be improved over a narrower bandwidth
by application of additional conjugate, linearity, or low
noise (Topt) matching.
4V
Vdd
1
IN
0.1uF
2
3
100pF
8
4
OUT
After adjusting the gate bias to obtain 138mA at Vdd = 4V,
the AMMP-6232 can be safely biased at 3V or 5V (while
fixing the gate bias) as desired. At 4V, the performance
is an optimal compromise between power consumption,
gain and power/linearity. It is both applicable to be used
as a low noise block or driver. At 3V, the amplifier is ideal
as a front end low noise block where linearity is not highly
required. At 5V, the amplifier can provide 1 to 2dBm more
output power for LO or transmitter driver applications
where high output power and linearity are often required.
100pF
7
6
5
0.1uF
Vg
~ -0.95V
Top View
Package base: GND
Refer the Absolute Maximum Ratings table for allowed DC
and thermal conditions.
Figure 19. Usage of the AMMP-6232
Figure 20. Evaluation/Test Board (available to qualified customer request)
Vd1
Matching
Network
In
Vg1
Figure 21. Simplified AMMP-6232 Schematic
Vd2
Matching
Network
Matching
Network
Vg2
Out
Recommended SMT Attachment for 5x5 Package
Figure 22a. Suggested PCB Land Pattern and Stencil Layout
Figure 22b. Stencil Outline Drawing (mm)
The AMMP Packaged Devices are compatible with high
volume surface mount PCB assembly processes.
The PCB material and mounting pattern, as defined in
the data sheet, optimizes RF performance and is strongly
recommended. An electronic drawing of the land pattern
is available upon request from Avago Sales & Application
Engineering.
Figure 22c. Combined PCB and Stencil Layouts
Manual Assembly
• Follow ESD precautions while handling packages.
• Handling should be along the edges with tweezers.
• Recommended attachment is conductive solder paste. Please see recommended solder reflow profile. Neither
Conductive epoxy or hand soldering is recommended.
• Apply solder paste using a stencil printer or dot
placement. The volume of solder paste will be
dependent on PCB and component layout and should
be controlled to ensure consistent mechanical and
electrical performance. • Follow solder paste and vendor’s recommendations
when developing a solder reflow profile. A standard
profile will have a steady ramp up from room
temperature to the pre-heat temp. to avoid damage
due to thermal shock. • Packages have been qualified to withstand a peak
temperature of 260°C for 20 seconds. Verify that the
profile will not expose device beyond these limits.
300
Peak=250±5˚C
Temp (˚C)
250
Meltingpoint=218˚C
200
150
100
50
0
Ramp1
0
50
Preheat Ramp2
100
Reflow
150
200
Cooling
250
300
Seconds
Figure 23. Suggested Lead-Free Reflow Profile for SnAgCu Solder Paste
AMMP-6232 Part Number Ordering Information
Part Number
Devices Per Container
Container
AMMP-6232-BLKG
10
Antistatic bag
AMMP-6232-TR1G
100
7” Reel
AMMP-6232-TR2G
500
7” Reel
A properly designed solder screen or stencil is required to
ensure optimum amount of solder paste is deposited onto
the PCB pads. The recommended stencil layout is shown
in Figure 22. The stencil has a solder paste deposition
opening approximately 70% to 90% of the PCB pad. Reducing stencil opening can potentially generate more
voids underneath. On the other hand, stencil openings
larger than 100% will lead to excessive solder paste smear
or bridging across the I/O pads. Considering the fact that
solder paste thickness will directly affect the quality of
the solder joint, a good choice is to use a laser cut stencil
composed of 0.127mm (5 mils) thick stainless steel which
is capable of producing the required fine stencil outline.
The most commonly used solder reflow method is
accomplished in a belt furnace using convection heat
transfer. The suggested reflow profile for automated
reflow processes is shown in Figure 23. This profile is
designed to ensure reliable finished joints. However, the
profile indicated in Figure 1 will vary among different
solder pastes from different manufacturers and is shown
here for reference only.
Package, Tape & Reel, and Ordering Information
.011
Top View
Side View
NOTES:
DIMENSIONS ARE IN INCHES [MILIMETERS]
ALL GROUNDS MUST BE SOLDERED TO PCB RF
Material is Rogers RO4350, 0.010” thick
Back View
Carrier Tape and Pocket Dimensions
For product information and a complete list of distributors, please go to our web site:
www.avagotech.com
Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies, Limited in the United States and other countries.
Data subject to change. Copyright © 2006 Avago Technologies Limited. All rights reserved. Obsoletes AV01-0442EN
AV02-0491EN - June 12, 2007