AVAGO MGA-43003 High linearity (1.805 â 1.88) ghz power amplifi er module Datasheet

MGA-43003
High Linearity (1.805 – 1.88) GHz Power Amplifier Module
Data Sheet
Description
Features
Avago Technologies’ MGA-43003 is a fully matched power
amplifier for use in the (1.805-1.88) GHz band. High linear
output power at 5V is achieved through the use of Avago
Technologies’ proprietary 0.25um GaAs Enhancementmode pHEMT process. MGA-43003 is housed in a miniature
5.0mm x 5.0mm molded-chip-on-board (MCOB) module
package. A detector is also included on-chip. The compact
footprint coupled with high gain, high linearity and good
efficiency makes the MGA-43003 an ideal choice as a
power amplifier for small cell BTS PA applications.
 High linearity performance : Typ -48dBc ACLR1 [1] at
27.0dBm linear output power (biased with 5V supply)
Applications
Specifications
 Final stage high linearity amplifier for Picocell and
Enterprise Femtocell PA targeted for small cell BTS
downlink applications.
1.842GHz; 5.0V, Idq=360mA (typ), LTE DL E-TM1.1, 20MHz
100RB, downlink signal
Component Image
 27.0dBm linear Pout @ ACLR1 =-48dBc [1]
5.0 x 5.0 x 0.9 mm Package Outline
AVAGO
Notes:
Package marking provides orientation
and identification
”43003” = Device part number
”YYWW” = Year and work week
”XXXX” = Assembly lot number
43003
YYWW
XXXX
 High Gain : 41.7dB
 Good efficiency
 Fully matched
 Built-in detector
 GaAs E-pHEMT Technology [2]
 Low cost small package size: (5.0 x 5.0 x 0.9) mm
 PAE : 14%
 41.7dB Gain
 Detector range : 20dB
Note:
1. LTE DL E-TM1.1, 20MHz 100RB, downlink signal
2. Enhancement mode technology employs positive Vgs, thereby
eliminating the need of negative gate voltage associated with
conventional depletion mode devices.
Functional Block Diagram
TOP VIEW
Vdd1
Vdd3
Vdd3
23
22
Gnd
24 Vdd3
25
26 Vdd2
27 Gnd
28 Vdd1
Pin Configuration
RFin
Gnd 1
21 Gnd
Gnd 2
20 Gnd
NC
3
19 RFout
RFin 4
18 RFout
NC
17 RFout
5
16 Gnd
Gnd 6
Gnd 13
15 Gnd
Vdet 14
VddBias 12
11
9
Gnd
8
Vc2
Vc3 10
(5.0 x 5.0 x 0.9) mm
7
Vc1
NC
Vdd2
1st Stage
Vdd3
2nd Stage
3rd Stage
RFout
Biasing Circuit
Vc1 Vc2 Vc3
VddBias
Vdet
Attention: Observe precautions for
handling electrostatic sensitive devices.
ESD Machine Model = 60 V
ESD Human Body Model = 400 V
Refer to Avago Application Note A004R:
Electrostatic Discharge, Damage and Control.
Absolute Maximum Rating [1] TA = 25° C
Thermal Resistance [2,3]
Symbol
Parameter
Units
Absolute Max.
Vdd, VddBias
Supply voltages, bias supply voltage
V
6
Vc
Control Voltage
V
(Vdd)
Pin,max
CW RF Input Power
dBm
20
Pdiss
Total Power Dissipation [3]
W
7.2
Tj
Junction Temperature
C
150
TSTG
Storage Temperature
C
-65 to 150
jc = 14°C/W
Notes:
1. Operation of this device in excess of any
of these limits may cause permanent
damage.
2. Thermal resistance measured using InfraRed Measurement Technique at Vdd=5.5V
operating voltage.
3. Board temperature (TB) is 25 °C , for
TB >49.2°C derate the device power at
71.4mW per °C rise in Board (package
belly) temperature.
Electrical Specifications
TA = 25C, Vdd1,2,3 = VddBias=5.0V, Idqtotal = 360mA, RF performance at 1.842GHz, LTE DL E-TM1.1, 20MHz 100RB
downlink signal operation unless otherwise stated.
Symbol
Parameter and Test Condition
Units
Vdd
Supply Voltage
V
5.0
Iqtotal
Quiescent Supply Current
mA
360
Gain
Gain
dB
OP1dB
Output Power at 1dB Gain Compression
dBm
36.8
ACLR1 @ Pout=27.0dBm
LTE DL E-TM1.1, 20MHz 100RB downlink signal
dBc
-48
PAE
Power Added Efficiency
%
S11
Input Return Loss, 50Ω source
dB
14
DetR
Detector RF dynamic range
dB
20
2fo
2fo Harmonics
(LTE DL E-TM1.1, 20MHz 100RB downlink signal)
dBc
-40
2
Min.
35
12
Typ.
Max.
41.7
14
-45
Product Consistency Distribution Charts [1]
LSL
LSL
35
36
37
38
39
40
41
42
43
44
Figure 1. Gain at Pout=27.0dBm; LSL=35.0dB, Nominal = 41.7dB
12
14
13
15
16
Figure 2. PAE at Pout=27.0dBm; LSL=12.0% Nominal = 14.1%
USL
0.6
0.64
0.68
0.72
0.76
Figure 3. Idd_total at Pout=27.0dBm, Nominal = 720mA
0.8
-54
-52
-50
-48
-46
-44
Figure 4. ACLR1 at Pout=27.0dBm, Nominal = -48.7dBc
Note:
1. Distribution data sample size is 3853 samples taken from 3 different wafer lots. TA = 25°C, Vdd=VddBias = 5.0V, Vc1=1.8V, Vc2=1.6V, Vc3=2.0V, RF
performance at 1.842GHz unless otherwise stated. Future wafers allocated to this product may have nominal values anywhere between the upper
and lower limits.
3
MGA-43003 typical over-temperature performance at Vc1=1.8V, Vc2=1.6V, Vc3=2.0V as shown in Figure 23 unless
otherwise stated
S21,S11,S22/dB
S21,S11,S22/dB
50
45
40
S21
35
30
25
20
15
10
5
0
-5
S11
-10
-15
-20
85qC
-25
S22
-30
25qC
-35
-40qC
-40
0.8 0.9 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 2.0 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8
Frequency/GHz
Figure 6. Small-signal performance Over-temperature
Vdd=VddBias=5.5V operating voltage
-36
-40
18
-40
18
-44
15
-44
15
ACLR1_-40qC
PAE_-40qC
6
-56
6
3
-60
3
0
-64
-60
21
22
23
24
25
Pout/dBm
26
27
28
29
24
ACLR1_-40qC
PAE_-40qC
22
23
24
25
26
27
28
29
30
24
ACLR1_85qC
PAE_85qC
ACLR1_25qC
PAE_25qC
ACLR1_-40qC
PAE_-40qC
21
-36
-40
18
-40
18
-44
15
-44
15
-48
12
-48
12
-52
9
-52
9
-56
6
-56
6
-60
3
-60
3
-64
0
-64
18
19
20
21
22
23
24
25
26
27
Pout/dBm
Figure 9. Over-temperature ACLR1, PAE vs Pout @ 1.842GHz
Vdd=VddBias=5.0V operating voltage
4
21
-32
28
29
30
PAE/%
ACLR1/dBc
-36
20
Figure 8. Over-temperature ACLR1, PAE vs Pout @ 1.815GHz
Vdd=VddBias=5.5V operating voltage
-32
ACLR1_25qC
PAE_25qC
19
Pout/dBm
Figure 7. Over-temperature ACLR1, PAE vs Pout @ 1.815GHz
Vdd=VddBias=5.0V operating voltage
ACLR1_85qC
PAE_85qC
0
18
30
21
0
18
19
20
21
22
23
24
25
26
27
Pout/dBm
Figure 10. Over-temperature ACLR1, PAE vs Pout @ 1.842GHz
Vdd=VddBias=5.5V operating voltage
28
29
30
PAE/%
20
21
12
-56
19
ACLR1_-40qC
PAE_-40qC
9
9
18
ACLR1_25qC
PAE_25qC
-52
12
-52
-64
24
ACLR1_85qC
PAE_85qC
-48
-48
ACLR1/dBc
ACLR1/dBc
ACLR1_25qC
PAE_25qC
ACLR1/dBc
-32
21
ACLR1_85qC
PAE_85qC
-36
PAE/%
24
-32
PAE/%
Figure 5. Small-signal performance Over-temperature
Vdd=VddBias=5.0V operating voltage
50
45
40
S21
35
30
25
20
15
10
5
0
-5
S22
-10
-15
-20
85qC
-25
S11
25qC
-30
-35
-40qC
-40
0.8 0.9 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 2.0 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8
Frequency/GHz
MGA-43003 typical over-temperature performance at Vc1=1.8V, Vc2=1.6V, Vc3=2.0V unless otherwise stated
-32
21
-36
-40
18
-40
-44
15
-48
12
-52
ACLR1_-40qC
PAE_-40qC
ACLR1/dBc
ACLR1_25qC
PAE_25qC
ACLR1_25qC
PAE_25qC
ACLR1_-40qC
PAE_-40qC
21
18
15
-48
12
9
-52
9
-56
6
-56
6
-60
3
-60
3
-64
0
-64
18
19
20
21
22
23
24
25
Pout/dBm
26
27
28
29
30
Idd_total/ mA
1800
1700
1600
1500
1400
1300
1200
1100
1000
900
800
700
600
500
400
300
PAE/%
-44
Figure 11. Over-temperature ACLR1, PAE vs Pout @ 1.87GHz
Vdd=VddBias=5.0V operating voltage
18
19
20
21
22
23
24
25
Pout/dBm
26
27
28
29
30
0
Figure 12. Over-temperature ACLR1, PAE vs Pout @ 1.87GHz
Vdd=VddBias=5.5V operating voltage
Idd_Total_85qC
Idd_Total_25qC
Idd_Total_-40qC
15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35
Pout/dBm
Figure 13. Over-temperature Idd_total vs Pout @ 1.842GHz
Vdd=VddBias=5.0V operating voltage
Figure 15. Over-temperature Vdet vs Pout @ 1.842 GHz, Vdd=VddBias=5.5V
operating voltage
5
24
ACLR1_85qC
PAE_85qC
ACLR1/dBc
24
ACLR1_85qC
PAE_85qC
-36
Figure 14. Over-temperature Vdet vs Pout @ 1.842 GHz, Vdd=VddBias=5.0V
operating voltage
PAE/%
-32
MGA-43003 typical over-temperature performance at Vc1=1.8V, Vc2=1.6V, Vc3=2.0V unless otherwise stated
-23
- 23
ACLR1_85qC
PAE_85qC
-28
ACLR1_-40qC
PAE_-40qC
-33
-38
-43
-48
-53
-58
-48
-53
-58
-63
-68
-73
20
21
22
23
24
25
Pout/dBm
26
27
28
29
30
18
-14
2fo_85qC
3fo_85qC
2fo_25qC
3fo_25qC
19
2fo_-40qC
3fo_-40qC
Gain/dB
-22
-26
1825
1835
1845
1855
1865
22
1875
1885
24
25
Pout/dBm
26
27
28
29
30
2300
43.0
2000
42.0
1700
41.0
1400
40.0
1100
39.0
800
37.0
24
1895
Gain_85qC
Idd_total_85qC
25
26
27
28
Gain_25qC
Idd_total_25qC
29
Frequency/MHz
Figure 18. Over-temperature 2nd, 3rd Harmonics vs Freq at Pout=27.2dBm,
Vdd=VddBias=5.0V operating voltage
30 31 32
Pout/dBm
500
Gain_-40qC
Idd_total_-40qC
33
34
35
36
37
38
200
Figure 19. Over-temperature Gain, Idd_total vs Pout @ 1.815GHz
Vdd=VddBias=5.0V operating voltage
2300
44.0
2300
43.0
2000
43.0
2000
42.0
1700
42.0
1700
41.0
1400
41.0
1400
40.0
1100
40.0
1100
39.0
800
39.0
800
500
38.0
200
37.0
24
38.0
37.0
24
Gain_85qC
Idd_total_85qC
25
26
27
28
Gain_25qC
Idd_total_25qC
29
30 31 32
Pout/dBm
Gain_-40qC
Idd_total_-40qC
33
34
35
36
37
Figure 20. Over-temperature Gain, Idd_total vs Pout @ 1.842GHz
Vdd=VddBias=5.0V operating voltage
38
Gain/dB
44.0
Idd_total/mA
Gain/dB
23
44.0
38.0
1815
21
Figure 17. Over-temperature ACLR1, ACLR2 vs Pout @ 1.842GHz
Vdd=VddBias=5.5V operating voltage
-18
-30
1805
20
Idd_total/mA
19
Gain_85qC
Idd_total_85qC
25
26
27
28
Gain_25qC
Idd_total_25qC
29
30 31 32
Pout/dBm
500
Gain_-40qC
Idd_total_-40qC
33
34
35
36
200
37
Figure 21. Over-temperature Gain, Idd_total vs Pout @ 1.87GHz
Vdd=VddBias=5.0V operating voltage
38
Idd_total/mA
18
-10
6
ACLR1_-40qC
PAE_-40qC
-43
-68
Figure 16. Over-temperature ACLR1, ACLR2 Pout @ 1.842GHz
Vdd=VddBias=5.0V operating voltage
2fo,3fo/dBm
ACLR1_25qC
PAE_25qC
-38
-63
-73
ACLR1_85qC
PAE_85qC
-28
ACLR1,ACLR2/ dBc
ACLR1,ACLR2/ dBc
-33
ACLR1_25qC
PAE_25qC
MGA-43003 typical LTE DL E-TM1.1, 20MHz 100RB downlink signal Spectrum Emission Mask (3GPP TS 36.141v8.2.0
[2009-03] standard) performance at Vdd=VddBias=5.0V, Vc1=1.8V, Vc2=1.6V, Vc3=2.0V unless otherwise stated
-25
-20
-15
-10
5
-5
0
Frequency Offset/MHz
10
15
20
25
Figure 22. SEM at Pout=29dBm @ 1.815GHz
-25
-20
-15
-10
5
-5
0
Frequency Offset/MHz
Figure 24. SEM at Pout=29dBm @ 1.87GHz
7
-25
-20
-15
-10
5
-5
0
Frequency Offset/MHz
Figure 23. SEM at Pout=29dBm @ 1.842GHz
10
15
20
25
10
15
20
25
S-Parameter [5] (Vdd=VddBias=5.0V, Vc1=1.8V, Vc2=1.6V, Vc3=2.0V), T=25 C, 50ohm matched)
Freq
S11
S11
S21
S21
S12
S12
S22
S22
(GHz)
(dB)
(ang)
(dB)
(ang)
(dB)
(ang)
(dB)
(ang)
0.1
0.02
-12.18
-53.22
-113.21
-61.81
-61.45
-0.33
174.99
0.2
-0.05
-24.76
-62.17
91.05
-59.88
16.11
-0.71
172.67
0.3
-0.13
-37.48
-50.87
49.37
-61.41
-8.51
-1.00
171.15
0.4
-0.15
-50.25
-27.10
26.63
-62.19
16.69
-1.22
170.39
0.5
-0.23
-62.53
-17.17
-106.40
-66.10
-38.14
-1.23
170.94
0.6
-0.21
-75.28
-10.72
-16.93
-67.69
3.06
-0.86
165.36
0.7
-0.70
-90.22
14.88
-112.32
-61.38
-15.52
-1.57
164.23
0.8
-0.78
-98.74
16.50
146.55
-73.02
117.70
-1.99
164.17
0.9
-0.74
-112.15
16.51
90.18
-60.95
-20.09
-1.97
167.39
1.0
-2.01
-125.59
23.25
140.55
-59.10
101.96
-1.96
162.80
1.1
-1.48
-132.03
30.98
33.36
-58.75
95.96
-0.48
165.02
1.2
-1.75
-148.04
32.31
-13.95
-59.09
92.21
-0.34
156.35
1.3
-2.37
-164.49
34.10
-52.54
-59.72
85.52
-0.48
148.90
1.4
-3.35
177.93
36.14
-88.47
-59.83
90.76
-0.81
140.82
1.5
-4.85
158.44
38.39
-125.22
-58.44
79.14
-1.47
130.92
1.6
-7.33
137.04
40.54
-165.96
-61.01
93.92
-2.99
118.37
1.7
-10.96
115.06
42.07
148.46
-56.02
74.28
-6.31
105.66
1.8
-14.92
86.57
42.53
100.93
-53.82
65.28
-13.68
107.12
1.9
-15.94
25.56
42.01
54.32
-53.16
53.46
-16.70
-163.90
2.0
-11.09
-34.91
40.62
10.02
-54.51
29.22
-8.63
-146.33
2.1
-7.88
-74.95
37.99
-30.72
-52.38
8.13
-4.61
-153.16
2.2
-5.26
-98.87
35.59
-63.76
-54.74
-12.61
-2.41
-163.53
2.3
-4.32
-122.98
32.42
-95.66
-58.92
-12.13
-1.34
-173.20
2.4
-4.28
-140.69
28.98
-121.61
-60.91
-18.61
-0.84
179.27
2.5
-4.61
-153.25
25.61
-142.42
-61.09
-12.03
-0.58
173.34
2.6
-4.86
-162.31
22.64
-159.89
-63.46
-4.17
-0.43
168.67
2.7
-5.16
-170.59
19.79
-177.05
-66.55
-63.25
-0.33
164.81
2.8
-5.57
-177.31
16.92
167.26
-66.50
-24.26
-0.27
161.52
2.9
-6.00
177.57
14.06
152.66
-70.35
-61.20
-0.22
158.59
3.0
-6.41
173.63
11.11
138.82
-63.63
-21.39
-0.19
155.95
3.1
-6.74
170.48
7.91
125.69
-67.73
8.56
-0.17
153.58
3.2
-7.05
168.22
4.20
113.39
-68.24
-32.37
-0.15
151.39
3.3
-7.27
166.88
-0.77
103.68
-69.91
31.40
-0.14
149.31
3.4
-7.39
165.96
-9.14
112.95
-63.83
27.19
-0.12
147.35
3.5
-7.29
165.72
-8.62
-166.09
-66.55
37.37
-0.12
145.44
3.6
-6.98
164.79
-1.67
-167.55
-64.47
44.29
-0.13
143.64
3.7
-6.52
162.00
1.30
170.54
-62.24
30.98
-0.16
141.93
3.8
-6.28
157.47
1.95
145.51
-62.33
-0.72
-0.17
140.39
3.9
-6.30
152.98
1.10
122.79
-65.81
43.97
-0.16
138.88
4.0
-6.52
149.50
-0.61
104.10
-63.27
4.34
-0.17
137.36
4.1
-6.72
147.31
-2.94
89.19
-65.10
48.03
-0.17
135.76
4.2
-6.87
145.97
-6.33
81.65
-63.92
20.30
-0.17
134.12
8
S-Parameter [5] (Vdd=VddBias=5.0V, Vc1=1.8V, Vc2=1.6V, Vc3=2.0V), T=25 C, 50ohm matched) Cont.
Freq
S11
S11
S21
S21
S12
S12
S22
S22
(GHz)
(dB)
(ang)
(dB)
(ang)
(dB)
(ang)
(dB)
(ang)
4.3
-6.79
145.06
-6.45
107.23
-60.57
40.03
-0.20
132.54
4.4
-6.96
142.22
-4.10
68.90
-68.21
51.65
-0.21
131.15
4.5
-7.10
142.38
-7.49
47.19
-67.57
58.95
-0.20
129.43
4.6
-6.95
142.44
-11.52
37.89
-62.71
63.97
-0.20
127.81
4.7
-6.73
140.79
-13.72
46.27
-60.40
36.87
-0.22
126.09
4.8
-6.77
139.70
-14.73
36.88
-65.41
38.72
-0.24
124.36
4.9
-6.63
139.90
-17.65
27.01
-62.36
60.80
-0.25
122.55
5.0
-6.44
139.23
-22.00
23.96
-61.98
37.52
-0.28
120.14
5.1
-6.19
136.72
-27.45
42.11
-60.09
40.81
-0.31
117.42
5.2
-5.45
132.68
-28.97
84.01
-58.87
29.68
-0.33
115.51
5.3
-4.86
124.46
-29.44
134.62
-58.95
22.78
-0.34
113.63
5.4
-4.95
113.92
-16.70
-2.45
-57.28
3.49
-0.38
111.56
5.5
-5.58
105.38
-5.38
139.67
-56.66
-11.62
-0.51
109.48
5.6
-6.53
98.03
-2.17
60.33
-60.03
-38.51
-0.57
109.13
5.7
-7.60
95.21
-5.78
15.29
-64.40
-36.65
-0.44
107.45
5.8
-8.37
93.99
-8.46
-7.79
-64.51
-5.03
-0.42
105.20
5.9
-8.91
93.42
-9.93
-26.68
-67.65
7.36
-0.42
103.15
6.0
-9.28
93.03
-10.11
-50.17
-65.82
-11.19
-0.45
100.97
7.0
-9.44
88.94
-43.86
-20.96
-65.23
1.20
-0.33
81.15
8.0
-6.99
92.65
-38.89
14.17
-59.33
-19.34
-0.25
57.99
9.0
-5.37
94.02
-38.76
-24.58
-59.43
-25.98
-0.31
34.72
10.0
-5.34
82.43
-38.90
-60.68
-57.52
-30.13
-0.73
10.01
11.0
-5.90
51.47
-40.96
-105.14
-59.26
-90.50
-0.80
-12.94
12.0
-4.59
19.47
-44.46
-140.43
-59.54
-82.99
-0.53
-31.07
13.0
-2.66
14.93
-48.34
-158.88
-62.23
-85.69
-0.31
-45.43
14.0
-1.76
22.63
-45.78
170.33
-63.35
-13.45
-0.46
-62.69
15.0
-2.29
9.47
-48.60
95.13
-52.08
-26.50
-0.87
-86.21
16.0
-2.94
-49.06
-47.19
14.21
-48.33
-67.90
-0.77
-103.76
17.0
-1.84
-108.03
-43.74
-50.70
-46.28
-82.71
-0.58
-109.24
18.0
-3.97
-7.55
-40.92
-94.62
-42.77
-119.59
-0.17
-108.26
19.0
-3.37
32.65
-41.60
-3.51
-43.88
-164.24
-0.26
-116.06
20.0
-1.76
13.85
-44.07
-144.61
-45.33
-144.82
-0.50
-130.43
9
S-Parameter [5] (Vdd=VddBias=5.5V, Vc1=1.8V, Vc2=1.6V, Vc3=2.0V), T=25 C, 50ohm matched)
Freq
S11
S11
S21
S21
S12
S12
S22
S22
(GHz)
(dB)
(ang)
(dB)
(ang)
(dB)
(ang)
(dB)
(ang)
0.1
0.02
-12.26
-52.99
32.05
-55.38
-165.54
-0.34
175.02
0.2
-0.05
-24.76
-58.04
-113.23
-57.83
-41.45
-0.71
172.83
0.3
-0.14
-37.49
-50.90
76.80
-59.78
-127.57
-0.98
171.30
0.4
-0.15
-50.21
-26.79
25.07
-62.51
105.44
-1.18
170.44
0.5
-0.24
-62.52
-16.75
-107.05
-60.46
91.97
-1.19
170.90
0.6
-0.22
-75.28
-10.17
-18.11
-60.75
-151.29
-0.84
165.51
0.7
-0.72
-90.20
15.20
-113.74
-64.79
-10.97
-1.51
164.20
0.8
-0.79
-98.69
16.88
146.06
-68.09
127.58
-1.91
163.99
0.9
-0.75
-112.12
17.03
90.15
-60.23
-11.50
-1.94
166.97
1.0
-2.04
-125.41
23.87
137.41
-61.24
134.02
-1.92
162.77
1.1
-1.50
-132.01
31.33
31.53
-59.37
95.45
-0.49
164.49
1.2
-1.80
-148.07
32.67
-15.64
-62.22
107.74
-0.36
155.93
1.3
-2.47
-164.56
34.43
-54.27
-61.65
77.08
-0.50
148.55
1.4
-3.50
177.91
36.45
-90.23
-62.11
84.84
-0.85
140.40
1.5
-5.11
158.82
38.66
-127.04
-61.01
100.53
-1.54
130.64
1.6
-7.70
138.20
40.75
-167.80
-56.98
83.96
-3.07
117.99
1.7
-11.47
118.35
42.21
146.88
-55.45
71.63
-6.52
105.84
1.8
-15.52
91.99
42.65
99.90
-54.32
76.98
-13.86
108.14
1.9
-16.59
27.79
42.14
53.80
-53.27
57.81
-16.53
-163.36
2.0
-11.30
-35.55
40.80
9.74
-53.44
20.87
-8.68
-146.65
2.1
-7.80
-75.81
38.24
-31.01
-53.41
3.79
-4.62
-152.91
2.2
-5.22
-99.77
35.83
-64.10
-54.43
-19.54
-2.39
-163.22
2.3
-4.27
-123.91
32.67
-96.12
-59.46
-11.06
-1.32
-173.05
2.4
-4.25
-141.60
29.22
-122.05
-62.04
-32.43
-0.82
179.31
2.5
-4.58
-154.07
25.85
-142.85
-61.00
-21.77
-0.57
173.40
2.6
-4.85
-163.04
22.87
-160.27
-64.78
-57.14
-0.43
168.76
2.7
-5.17
-171.17
20.02
-177.39
-64.36
3.87
-0.33
164.90
2.8
-5.56
-177.79
17.14
166.98
-64.78
-25.02
-0.27
161.57
2.9
-6.00
177.13
14.28
152.48
-66.20
47.47
-0.22
158.68
3.0
-6.40
173.35
11.33
138.70
-75.73
43.47
-0.18
156.09
3.1
-6.73
170.30
8.13
125.65
-66.66
25.20
-0.16
153.72
3.2
-7.02
168.15
4.44
113.38
-65.99
64.41
-0.14
151.54
3.3
-7.23
166.81
-0.52
103.74
-65.73
20.30
-0.13
149.47
3.4
-7.34
165.92
-8.88
113.21
-68.13
48.97
-0.11
147.53
3.5
-7.24
165.88
-8.28
-166.14
-61.78
25.49
-0.11
145.63
3.6
-6.90
164.90
-1.33
-168.00
-67.35
82.38
-0.13
143.84
3.7
-6.43
161.99
1.61
169.76
-61.69
26.24
-0.15
142.15
3.8
-6.20
157.42
2.21
144.60
-61.13
36.14
-0.16
140.60
3.9
-6.25
152.81
1.29
121.96
-68.09
70.71
-0.16
139.12
4.0
-6.45
149.46
-0.45
103.48
-67.82
-37.04
-0.16
137.62
4.1
-6.66
147.31
-2.80
88.77
-66.35
16.58
-0.17
136.03
4.2
-6.81
146.03
-6.20
81.63
-65.67
42.55
-0.17
134.46
10
S-Parameter [5] (Vdd=VddBias=5.5V, Vc1=1.8V, Vc2=1.6V, Vc3=2.0V), T=25 C, 50ohm matched) Cont.
Freq
S11
S11
S21
S21
S12
S12
S22
S22
(GHz)
(dB)
(ang)
(dB)
(ang)
(dB)
(ang)
(dB)
(ang)
4.3
-6.73
145.09
-6.23
106.85
-65.05
33.32
-0.20
132.86
4.4
-6.90
142.21
-3.98
68.76
-67.23
36.21
-0.21
131.52
4.5
-7.04
142.33
-7.36
47.30
-66.38
35.96
-0.19
129.86
4.6
-6.90
142.38
-11.36
38.21
-62.34
14.90
-0.20
128.24
4.7
-6.69
140.65
-13.54
46.44
-63.24
37.89
-0.21
126.50
4.8
-6.74
139.57
-14.54
36.92
-62.19
56.23
-0.23
124.74
4.9
-6.61
139.68
-17.48
27.16
-62.79
42.79
-0.24
122.95
5.0
-6.43
138.98
-21.83
24.15
-59.87
29.35
-0.27
120.51
5.1
-6.19
136.43
-27.31
42.39
-62.62
50.95
-0.30
117.75
5.2
-5.48
132.32
-28.76
84.21
-58.57
29.40
-0.32
115.82
5.3
-4.93
124.24
-29.21
135.36
-59.18
26.78
-0.34
113.92
5.4
-5.02
113.88
-16.47
-2.90
-58.22
12.27
-0.37
111.82
5.5
-5.65
105.57
-5.22
139.20
-57.13
-0.63
-0.51
109.71
5.6
-6.57
98.37
-2.09
60.18
-61.53
-44.07
-0.56
109.37
5.7
-7.62
95.50
-5.70
15.51
-65.35
1.13
-0.43
107.64
5.8
-8.35
94.38
-8.36
-7.49
-62.34
-29.35
-0.41
105.44
5.9
-8.88
93.72
-9.82
-26.15
-69.08
-30.82
-0.41
103.41
6.0
-9.22
93.31
-9.99
-49.72
-64.77
-19.58
-0.44
101.23
7.0
-9.40
88.81
-44.00
-19.50
-61.85
3.64
-0.31
81.41
8.0
-7.02
92.52
-38.56
16.91
-60.62
7.26
-0.25
58.37
9.0
-5.40
94.06
-38.50
-23.70
-59.21
-29.55
-0.33
35.08
10.0
-5.40
82.91
-38.71
-58.44
-57.47
-40.69
-0.73
10.52
11.0
-5.98
52.21
-40.79
-103.76
-59.42
-78.22
-0.80
-12.50
12.0
-4.67
20.54
-44.75
-140.47
-60.73
-94.41
-0.52
-30.11
13.0
-2.68
16.08
-47.88
-152.48
-61.73
-85.07
-0.31
-44.91
14.0
-1.80
23.47
-45.63
172.49
-61.57
-34.42
-0.42
-62.03
15.0
-2.31
10.32
-47.97
100.28
-51.49
-25.39
-0.87
-85.45
16.0
-2.97
-47.89
-47.56
12.07
-47.76
-67.84
-0.75
-103.23
17.0
-1.89
-107.22
-43.40
-46.37
-46.31
-83.79
-0.55
-108.08
18.0
-3.98
-7.49
-41.22
-93.11
-43.24
-120.74
-0.17
-107.59
19.0
-3.48
35.04
-41.01
-7.28
-43.70
-166.91
-0.24
-115.31
20.0
-1.89
14.22
-43.65
-143.65
-44.08
-144.54
-0.49
-129.83
Notes:
5.
S-parameter is measured with deembedded reference plane at DUT RFin and RFout pins.
11
Demonstration Board Top View (Vdd=VddBias=5.0V operating voltage)
Vdd1
+5V
Vdd2
+5V
Vdd3
+5V
C32
C24
C255CC28
CC29
C30
C31
Vc1=1.8V Vc3 =2.0V
VddBias
Vc2=1.6V +5V
Component
Value
Part Number
C1 , C2, C6, C18,
C20, C22, C24
8.2pF  0.5pF
GJM1555C1H8R2WB01D
C3, C8, C13, C25
0.1uF  10%
GRM155R71C104KA88D
C5, C32
82pF  5%
GRM1555C1H820JA01D
C10
2.2uF  10%
GRM21BR71E225KA73L
C26
22nF  10%
CM05X7R223K16AHF
R1
0
RMC1/10 JPTP
R2, R3, R4, R5
0
RMC1/16S JPTH
Note:
For performance optimization control voltage for invidual stages can be
adjusted by varying R2, R3 and R4 resistor value.
Vdet
(Output)
Vdd1
+5V
Vdd2
+5V
Vdd3
+5V
Application board pin
header assignments:
Pins pointing out of the page
(unit is on top)
1 2 3 4 5 6
C32
12 11 10 9 8 7
13 14 15 16 17
22 21 20 19 18
C24
C255CC28
CC29
C30
C31
Vdet
Vc1= Vc3 =
(Output)
1.8V
2.0V VddBias
+5V
Vc2=
1.6V
Figure 25. Demonstration board application circuit for MGA-43003 module
12
Pin 1 : Vdd3 (Sense)
Pin 2 : Vdd3 (Force)
Pin 3 : Vdd2 (Sense)
Pin 4 : Vdd2 (Force)
Pin 5 : Vdd1 (Sense)
Pin 6 : Vdd1 (Force)
Pin 13 : Vc1
Pin 14 : Vc2
Pin 15 : Vc3
Pin 16 : VddBias (Force)
Pin 17 : Vdet
Other pins are grounded
Application Schematic
Vdd2
Vdd1
Idq1
Vdd3
Idq2
C3
C8
C10
Idq3
C13
C5
C32
C6
1
RFin
RFout
C1
C2
Top View
C18
Vc1
C20
Vc2
C24
I_VddBias
C25
C22
Vc3
VddBias
C26
Vdet
Figure 26. Application schematic in demonstration board
Notes
1. All capacitors on supply lines are bypass capacitors
2. C1 / C2 are RF coupling capacitors.
3. Idq1= 55.0mA, Idq2 = 105.0mA, Idq3 = 200.0mA, I_VddBias = 14.0mA. Idq1/2/3 are adjusted by voltages to CMOS-compatible control pins Vc1/2/3
respectively. These typical bias currents were obtained with Vc1/2/3 voltages in Figure 23 above. Adjustment of these currents enable optimum
bias conditions to be achieved for best linearity and efficiency for a given modulation type.
13
125
120
115
110
105
100
95
90
85
80
75
70
2.0
Ic,uA
Ic,uA
MGA-43003 typical Ic2, Ic3 Vs Vc performance unless otherwise stated
Ic1
Ic2
Ic3
2.2
2.4
2.6
2.8
3.0
125
120
115
110
105
100
95
90
85
80
75
70
2.0
Ic1
Ic2
Ic3
2.2
2.4
Vc,V
2.6
2.8
3.0
Vc,V
Figure 27. Ic Versus Vc at Vdd=VddBias=5.0V
Figure 28. Ic Versus Vc at Vdd=VddBias=5.5V
PCB Land Pattern and Stencil Outline
4.77
5.00
3.60
0.23
0.50
1.13
0.82
0.45
0.80
Pin1
0.75
3.24
1.82
0.68
0.25
1.52
0.60
5.00
1.25
0.40
3.70
0.50
1.13
∅0.30
0.05
0.68
0.80
0.27
0.50
0.50
(pitch)
Soldermask
Opening
0.25
Stencil Opening
Land Pattern
5.00
3.60
3.24
0.45
Soldermask
Top Metal
3.60 5.00
Note :
1. Recommended Land Pattern and Stencil.
2. 4 mils stencil thickness recommended.
3. All dimensions are in mm
0.05
Combination of Land Pattern & Stencil Opening
14
4.77
MCOB (5.0 x 5.0 x 0.9) mm 28-Lead Package Dimensions
AVAGO
43003
YYWW
XXXX
Top View
Side View
Note
1. All dimensions are in millimeters.
2. Dimensions are inclusive of plating.
3. Dimensions are exclusive of mold flash and metal burr.
Part Number Ordering Information
Part Number
Qty
Container
MGA-43003-BLKG
100
Antistatic Bag
MGA-43003-TR1G
1000
7” Reel
15
Bottom View
Device Orientation
REEL
USER FEED DIRECTION
CARRIER
TAPE
USER
FEED
DIRECTION
Tape Dimensions
16
AVAGO
AVAGO
AVAGO
43003
YYWW
XXXX
43003
YYWW
XXXX
43003
YYWW
XXXX
TOP VIEW
COVER TAPE
END VIEW
Reel Dimensions (7” reel)
Ø178.0±1.0
FRONT
BACK
SEE DETAIL "X"
RECYCLE LOGO
FRONT VIEW
65°
7.9 - 10.9*
+1.5*
8.4
-0.0
45°
R10.65
R5.2
Slot hole ‘b’
BACK
60°
Ø55.0±0.5
Ø178.0±1.0
FRONT
Slot hole ‘a’
EMBOSSED RIBS
RAISED: 0.25mm, WIDTH: 1.25mm
Ø51.2±0.3
BACK VIEW
For product information and a complete list of distributors, please go to our web site:
14.4*
MAX.
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 © 2005-2016 Avago Technologies. All rights reserved.
AV02-4350EN - May 10, 2016
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