AVAGO AMMP-6441 36-40 ghz, 0.4w power amplifi er in smt package Datasheet

AMMP-6441
36 - 40 GHz, 0.4W Power Amplifier in SMT Package
Data Sheet
Description
Features
The AMMP-6441 MMIC is a 0.4W power amplifier in a
surface mount package designed for use in transmitters
that operate at frequencies between 36GHz and 40GHz. In
the operational band, it provides 26 dBm of output power
(P-1dB) and 20dB of small-signal gain.
 5x5mm SMT package
Applications
 Frequency range 36 to 40 GHz
 LMDS & Pt-Pt mmW Long Haul
 Small signal Gain of 20dB
 Microwave Radio systems
 Output power @P-1 of 26dBm (Typ.)
 WLL and MMDS loops
 Input and Output return losses -10dB
Package Diagram
Functional Block Diagram
Vg
1
RF IN
Vd1
2
 0.4 watt output power
 50  match on input and output
Typical Performance (Vd=5V, Idsq=0.45A)
Vd2
1
2
3
3
8
4
7
6
5
Vg
Vd1
Vd2
RF OUT
8
4
7
6
Pin
Function
1
2
3
4
5
6
7
8
Vg
Vd1
Vd2
RF OUT
Vd2
Vd1
Vg
RF IN
5
Note:
1. This MMIC uses depletion mode pHEMT devices.
Negative supply is used for DC gate biasing.
RoHS-Exemption
Attention: Observe Precautions for
handling electrostatic sensitive devices.
ESD Machine Model (Class A): 40V
ESD Human Body Model (Class 0): 150V
Refer to Avago Application Note A004R:
Electrostatic Discharge Damage and Control.
Please refer to hazardous substances table on page 10.
Note: MSL Rating = Level 2A
Electrical Specifications
1. Small/Large -signal data measured in a fully de-embedded test fixture form TA = 25°C.
2. Pre-assembly into package performance verified 100% on-wafer per AMMC-6120 published specifications.
3. This final package part performance is verified by a functional test correlated to actual performance at one or more
frequencies.
4. Specifications are derived from measurements in a 50 Ω test environment. Aspects of the amplifier performance may
be improved over a more narrow bandwidth by application of additional conjugate, linearity, or low noise (Гopt)
matching.
Table 1. RF Electrical Characteristics
TA=25°C, Vd=5.0V, Idq=0.45V, Vg=-1V, Zo=50 Ω
Parameter
Min
Typ.
Max
40
Unit
Operational Frequency, Freq
36
Small-signal Gain, Gain
18
20
dB
GHz
Output Power at 1dB Gain Compression, P-1dB
24.5
26
dBm
Relative Third Order Inter-modulation level
(Δf=10MHz, Po=+12dBm, SCL), IM3
-38
dBc
Input Return Loss, Rlin
10
dB
Output Return Loss, Rlout
10
dB
Reverse Isolation, Isolation
45
dB
Table 2. Recommended Operating Range
1. Ambient operational temperature TA = 25°C unless otherwise noted.
2. Channel-to-backside Thermal Resistance (Tchannel (Tc) = 34°C) as measured using infrared microscopy. Thermal
Resistance at backside temperature (Tb) = 25°C calculated from measured data.
Description
Min.
Typical
Drain Supply Current, Idq
Max.
450
Gate Supply Operating Voltage, Vg
-1.3
-1
-0.7
Unit
Comments
mA
Vd = 5V, Vg set for Id Typical
V
Idq=450mA
Table 3. Thermal Properties
Parameter
Test Conditions
Value
Channel Temperature, Tch
Thermal Resistance
(Channel-to-Base Plate), ch-bs
Tch=150 °C
Jc = 34 °C/W
Channel-to-backside Thermal Resistance Tchannel(Tc)=34°C
Thermal Resistance at backside temperature Tb=25°C
Note:
1. Assume SnPb soldering to an evaluation RF board at 85 °C base plate temperatures. Worst case is at saturated output power when DC power
consumption rises to 5.24W with 0.9W RF power delivered to load. Power dissipation is 4.34W and the temperature rise in the channel is 72.9 °C. In
this condition, the base plate temperature must be remained below 82.1 °C to maintain maximum operating channel temperature below 155 °C.
Absolute Minimum and Maximum Ratings
Table 4. Minimum and Maximum Ratings
Description Pin
Min.
Max.
Unit
5.5
V
-2
0
Drain Supply Voltage, Vd
Gate Supply Voltage, Vg
Power Dissipation, P¬D
3
CW Input Power, Pin
20
dBm
Channel Temperature
+150
°C
+155
°C
+260
°C
Storage Temperature
Maximum Assembly Temperature
-65
Notes:
1. Operation in excess of any one of these conditions may result in permanent damage to this device.
2
Comments
CW
30 second maximum
Typical Distribution Charts
LSL
LSL
20
21
22
23
24
18
Figure A. Gain @ 37GHz, Nominal = 23, LSL = 18
LSL
20
21
22
LSL
18
19
20
21
22
25
Figure C. Gain @ 40GHz, Nominal = 20, LSL = 18
26
27
28
Figure D. P1dB @ 37GHz, Nominal = 27, LSL = 24.5
LSL
LSL
25
26
27
Figure E. P1dB @ 38GHz, Nominal = 27, LSL = 24.5
3
19
Figure B. Gain @ 38GHz, Nominal = 21, LSL = 18
28
29
25
26
27
Figure F. P1dB @ 40GHz, Nominal = 28, LSL = 24.5
28
29
Typical Performance
(Data was obtained from a 2.4mm connector based test fixture and includes connector and board losses. Connector and
board loss is approximately 0.5dB at input and output ports for an approximate total of 1dB.)
(TA = 25°C, Vdd=5V, Idq=0.45 A, Vg=-1 V, Zin = Zout = 50 )
30
S21[dB]
S12[dB]
0
-35
-5
-40
15
-45
10
-50
5
-55
-20
-60
-25
0
30
32
34
36
38 40 42 44
Frequency [GHz]
46
48
30
8
Noise Figure [dB]
25
20
15
P-1
PAE@P1
P-3
PAE@P3
34
36
38 40 42 44
Frequency [GHz]
46
48
50
6
4
2
0
0
35
36
37
38
Frequency[GHz]
39
40
41
35
37
39
41
Frequency [GHz]
43
45
Figure 4. Typical noise figure
Figure 3. Typical output power (P-1 and P-3) vs. frequency
40
0
SCL=18[dBm]
SCL=12dBm]
SCL=4[dBm]
-20
35
Po[dBm], and, PAE[%]
-10
850
Pout(dBm)
PAE[%]
Id(total)
30
800
750
25
700
20
650
15
600
10
550
5
500
-60
0
450
-70
34
-5
-30
-40
-50
35
36
37
38
Frequency [GHz]
39
40
41
Figure 5. Typical third order inter-modulation product level vs. frequency at
different single carrier output level (SCL)
-25
-20
-15
-10
-5
Pin [dBm]
0
5
10
400
Figure 6. Typical output power, PAE, and total drain current versus Input
power at 40GHz
Ids [mA]
34
Relative IM3 Level [dBc]
32
Figure 2. Typical return Loss (input and output)
10
5
4
-15
30
10
S11[dB]
S22[dB]
-10
50
Figure 1. Typical gain and reverse Isolation
P1, P3 [dBm], PAE[%]
Return Loss [dB]
20
S12 [dB]
S21[dB]
25
-30
480
-20
-40
470
-50
465
-60
-70
-80
0
2
4
6
8
475
-40
470
-50
465
460
-60
460
455
-70
455
450
-80
IM3_h [dBc]
IM3_l [dBc]
Ids_total
490
0
485
-10
480
-20
-30
475
-40
470
-50
465
-60
-70
-80
0
2
4
6
8
-70
455
450
10 12 14 16 18 20 22
Po [dBc, SCL]
-80
0
4
6
8
450
10 12 14 16 18 20 22
Po [dBc, SCL]
0
485
-10
480
-20
490
IM3_h [dBc]
IM3_l [dBc]
Ids_total
485
480
-30
475
-40
470
-50
465
460
-60
460
455
-70
455
450
-80
-50
465
-60
-70
10 12 14 16 18 20 22
Po [dBc, SCL]
2
Figure 10. Typical IM3 level and Ids vs. single carrier output level at 38GHz
Ids [mA]
IM3 Level [dBc]
480
455
Figure 11. Typical IM3 level and Ids vs. single carrier output level at 39GHz
5
485
460
470
8
IM3_h [dBc]
IM3_l [dBc]
Ids_total
-60
-40
6
490
460
475
4
450
465
490
2
10 12 14 16 18 20 22
Po [dBc, SCL]
-50
IM3_h [dBc]
IM3_l [dBc]
Ids_total
0
8
470
-30
-80
6
-40
0
-20
4
475
Figure 9. Typical IM3 level and Ids vs. single carrier output level at 37GHz
-10
2
-30
Ids [mA]
IM3 Level [dBc]
-20
0
Figure 8. Typical IM3 level and Ids vs. single carrier output level at 36GHz
Figure 7. Typical IM3 level and Ids vs. single carrier output level at 35GHz
-10
480
-30
10 12 14 16 18 20 22
Po [dBc, SCL]
0
485
Ids [mA]
475
490
IM3_h [dBc]
IM3_l [dBc]
Ids_total
Ids [mA]
-30
IM3 Level [dBc]
-10
IM3 Level [dBc]
IM3 Level [dBc]
-20
485
IM3 Level [dBc]
-10
0
Ids [mA]
490
IM3_h [dBc]
IM3_l [dBc]
Ids_total
Ids [mA]
0
450
0
2
4
6
8
10 12 14 16 18 20 22
Po [dBc, SCL]
Figure 12. Typical IM3 level and Ids vs. single carrier output level at 40GHz
Typical over temperature dependencies
(Vdd =5 V, Id(q) = 0.45 A, Zin = Zout = 50 )
0
S21[dB]
S11[dB]
-5
-10
-15
S11_25
S11_-40
S11_85
-20
25
30
35
40
Frequency[GHz]
45
S22_25
S22_-40
S22_85
P-1 [dBm]
S22[dB]
-10
-15
-20
30
35
40
Frequency[GHz]
Figure 15. Typical S22 over temperature
6
30
35
40
Frequency[GHz]
45
50
Figure 14. Typical Gain over temperature
0
25
S21_25
S21_-40
S21_85
25
50
Figure 13. Typical S11 over temperature
-5
34
32
30
28
26
24
22
20
18
16
14
12
10
45
50
30
29
28
27
26
25
24
23
22
21
20
P-1_-40deg
P-1_25deg
P-1_85deg
35
36
37
38
39
Frequency [GHz]
Figure 16. Typical P1 over temperature
40
41
42
Typical Scattering Parameters [1], (TA = 25°C, Vd =5 V, ID = 0.45A, Zin = Zout = 50 )
S11
S11
S11
S21
S21
S21
S12
S12
S12
S22
S22
S22
Freq
[dB]
Mag.
Ang.
[dB]
Mag.
Ang.
[dB]
Mag.
Ang.
[dB]
Mag.
Ang.
20
-1.44
0.85
-29.26
-37.16
0.01
65.56
-63.28
6.86E-04
-177.94
-1.19
0.87
18.22
21
-1.63
0.83
-120.63
-29.23
0.03
-99.35
-54.49
1.89E-03
-40.70
-1.24
0.87
-78.33
22
-2.17
0.78
156.73
-28.37
0.04
118.06
-48.78
3.64E-03
-139.74
-1.40
0.85
-163.84
23
-2.54
0.75
82.21
-28.13
0.04
5.08
-43.64
6.58E-03
121.50
-1.70
0.82
118.20
24
-2.57
0.74
8.22
-25.49
0.05
-99.30
-46.26
4.87E-03
9.57
-2.03
0.79
42.54
25
-2.37
0.76
-72.68
-22.13
0.08
153.82
-48.56
3.73E-03
-50.55
-2.09
0.79
-37.40
26
-2.20
0.78
-157.58
-18.74
0.12
51.99
-49.99
3.17E-03
-95.33
-1.78
0.81
-125.00
27
-2.63
0.74
119.20
-15.74
0.16
-57.08
-47.44
4.24E-03
-162.87
-1.98
0.80
144.30
28
-3.60
0.66
38.52
-12.05
0.25
-151.97
-46.99
4.47E-03
129.19
-2.76
0.73
58.95
29
-4.45
0.60
-49.91
-9.02
0.35
103.37
-44.13
6.22E-03
52.66
-4.18
0.62
-26.18
30
-4.16
0.62
-146.99
-3.43
0.67
7.49
-42.45
7.54E-03
-34.31
-4.71
0.58
-119.60
31
-3.33
0.68
125.31
1.38
1.17
-104.04
-44.38
6.04E-03
-132.01
-4.83
0.57
145.56
32
-3.33
0.68
49.43
6.37
2.08
144.41
-48.04
3.96E-03
153.99
-6.19
0.49
64.25
33
-4.98
0.56
-26.60
11.65
3.83
27.95
-46.59
4.68E-03
77.28
-10.13
0.31
-4.65
34
-11.74
0.26
-113.03
17.79
7.75
-106.88
-49.08
3.51E-03
-10.06
-15.14
0.18
-19.11
35
-30.25
0.03
24.52
21.45
11.82
106.76
-55.81
1.62E-03
-98.22
-14.40
0.19
-72.40
36
-17.57
0.13
-87.74
23.79
15.47
-40.53
-60.09
9.90E-04
-129.51
-18.76
0.12
-108.00
37
-13.79
0.20
-164.97
23.65
15.22
162.26
-59.53
1.06E-03
-76.94
-17.05
0.14
132.26
38
-14.61
0.19
77.57
21.23
11.52
23.42
-59.27
1.09E-03
-175.64
-13.57
0.21
-1.64
39
-16.58
0.15
-61.70
19.06
8.98
-108.07
-51.41
2.69E-03
134.13
-9.87
0.32
-82.52
40
-17.09
0.14
-137.82
18.71
8.62
124.45
-52.74
2.31E-03
42.42
-9.66
0.33
-154.98
41
-9.75
0.33
131.82
16.44
6.64
-23.69
-67.37
4.28E-04
-5.49
-13.64
0.21
144.48
42
-9.63
0.33
43.60
12.18
4.07
-148.68
-54.05
1.98E-03
-18.28
-12.48
0.24
130.71
43
-15.69
0.16
-22.56
10.60
3.39
91.90
-51.44
2.68E-03
-84.16
-9.78
0.32
63.32
44
-10.14
0.31
-72.86
10.82
3.47
-51.05
-51.69
2.60E-03
-171.27
-9.37
0.34
-28.63
45
-9.64
0.33
-173.38
6.05
2.01
143.60
-46.06
4.98E-03
101.90
-8.56
0.37
-145.17
46
-10.16
0.31
117.40
-2.18
0.78
-7.04
-41.86
8.08E-03
-1.64
-7.06
0.44
107.01
47
-9.25
0.34
39.30
-12.11
0.25
-134.88
-38.15
1.24E-02
-106.69
-6.70
0.46
14.48
48
-9.23
0.35
-51.59
-20.73
0.09
124.23
-35.98
1.59E-02
164.73
-6.62
0.47
-69.34
49
-7.92
0.40
-143.04
-26.43
0.05
41.29
-31.88
2.55E-02
81.22
-6.92
0.45
-152.30
50
-7.21
0.44
132.95
-28.47
0.04
-47.16
-31.37
2.70E-02
-21.85
-7.65
0.41
127.63
Note:
1. Data obtained from 2.4-mm connecter based modules, and this data is including connecter loss, and board loss. The measurement reference plane
is at the RF connectors.
7
Biasing and Operation.
Recommended quiescent DC bias condition for optimum
power and linearity performances is Vd=5 volts with
Vg (-1V) set for Id=450 mA. Minor improvements in
performance are possible depending on the application.
The drain bias voltage range is 3 to 5V. A single DC gate
supply connected to Vg will bias all gain stages. Muting
can be accomplished by setting Vg to the pinch-off
voltage Vp (-2V).
Vg
0.1 PF
100 pF
0.1 PF
100 pF
1
A typical DC biasing connection is shown in Figure 17.
Vg and Vd can be biased from either side. The RF input
port is connected internally to ground; therefore, an input
decoupling capacitor is needed if the preceding output
stage has DC present. The RF output is DC decoupled
internally. No ground wired are needed since ground
connections are made with plated through-holes to the
backside of the device.
3
2
RF Input
RF Output
8
4
7
5
6
100 pF
0.1 PF
Figure 17. Schematic and recommended assemble example
Note: No RF performance degradation is seen due to ESD up to 150V
HBM and 40V MM. The DC characteristics in general show increased
leakage at higher ESD discharge voltages. The user is reminded that this
device is ESD sensitive and needs to be handled with all necessary ESD
protocols.
8
Notes:
1. Vd may be biased
from either side.
2. Vg may be biased
from either side.
Vd
AMMP-64xx Part Number Ordering Information
Devices Per
Container
Container
Part Number
AMMP-6441-BLKG
10
Antistatic bag
AMMP-6441-TR1G
100
7” Reel
AMMP-6441-TR2G
500
7” Reel
Package Dimension, PCB Layout and Tape and Reel information
Please refer to Avago Technologies Application Note 5520, AMxP-xxxx production Assembly Process (Land Pattern A).
Names and Contents of the Toxic and Hazardous Substances or Elements in the Products
Part Name
Toxic and Hazardous Substances or Elements
Lead
(Pb)
(Pb)
Mercury
(Hg)
Hg
Cadmium
(Cd)
Cd
Hexavalent
(Cr(VI))
Cr(VI)
Polybrominated
biphenyl (PBB)
PBB
100pF capacitor
: indicates that the content of the toxic and hazardous substance in all the homogeneous materials of the part is
below the concentration limit requirement as described in SJ/T 11363-2006.
: indicates that the content of the toxic and hazardous substance in at least one homogeneous material of the part
exceeds the concentration limit requirement as described in SJ/T 11363-2006.
(The enterprise may further explain the technical reasons for the “x” indicated portion in the table in accordance with
the actual situations.)
SJ/T 11363-2006
SJ/T 11363-2006
“×”
Note: EU RoHS compliant under exemption clause of “lead in electronic ceramic parts (e.g. piezoelectronic devices)”
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 in the United States and other countries.
Data subject to change. Copyright © 2005-2011 Avago Technologies. All rights reserved.
AV02-1908EN - June 21, 2011
Polybrominated
diphenylether (PBDE)
PBDE
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