AVAGO MGA

MGA-31716
0.1 W High Linearity Driver Amplifier
Data Sheet
Description
Features
Avago Technologies MGA-31716 is a high linearity driver
MMIC Amplifier housed in a standard QFN 3X3 16 lead
plastic package. It features high gain, low operating
current, low noise figure with good input and output
return loss. Power consumption can be further reduced
by reducing the quiescent bias current using two external
bias resistors. The device can be easily matched at different
frequencies to obtain optimal linearity performance at
those frequencies.
x Very high linearity at low DC bias power [1]
MGA-31716 is especially ideal for 50 : wireless infrastructure application operating from DC to 2 GHz frequency
range. With the high linearity, excellent gain flatness and
low noise figure the MGA-31716 may be utilized as a driver
amplifier in the transmit chain and as a second stage LNA
in the receiver chain.
x Lead-free MSL1
This device uses Avago Technologies proprietary 0.25 Pm
GaAs Enhancement mode PHEMT process.
Pin connections and Package Marking
x High Gain with good gain flatness
x ROHS compliant
x Good Noise Figure
x Halogen free
x Advanced enhancement-mode PHEMT Technology
x QFN 3X3 16-Lead standard package
Specifications
At 900 MHz, Vd = 5 V, Id = 58 mA (typ) @ 25° C
x OIP3 = 41.0 dBm
x Noise Figure = 1.9 dB
x Gain = 20.2 dB
x P1dB = 21.2 dBm
x IRL = 16.7dB, ORL = 15.9 dB
Note:
1. The MGA-31716 has a superior LFOM of 16.5 dB. Linearity-Figure-ofMerit (LFOM) is the ratio of OIP3 to total DC bias power.
31716
YYWW
XXXX
Attention: Observe precautions for
handling electrostatic sensitive devices.
ESD Machine Model = 60 V
ESD Human Body Model = 300 V
Refer to Avago Application Note A004R:
Electrostatic Discharge, Damage and Control.
TOP VIEW
Vbias 16
NC 14
Vctrl 15
Vd 13
NC 12
1 NC
RFout 11
2 NC
Gnd
RFout 10
3 RFin
NC 9
4 NC
5 NC
6 NC
7 NC
8 NC
NC - not connected
BOTTOM VIEW
Notes:
Package marking provides orientation and identification
“31716” = Device Part Number
“YYWW” = Work Week and Year of manufacturing
“XXXX” = Last 4 digit of Lot Number
Figure 1. Simplified Application Circuit
Table 1. MGA-31716 Absolute Maximum Rating [1] TA = 25° C
Thermal Resistance
Symbol
Parameter
Units
Absolute Maximum
Vd, max
Drain Voltage
V
5.5
Vbias, max
Bias Voltage
V
5.5
Vctrl, max
Control Voltage
V
5.5
Pd
Power Dissipation [2]
mW
605
Pin
CW RF Input Power
dBm
24
Tj
Junction Temperature
°C
150
Tstg
Storage Temperature
°C
-65 to 150
Tamb
Ambient Temperature
°C
-40 to 85
Thermal Resistance [3]
(Vd = 5.0 V, Tc = 85° C) Tjc = 67.0°C/W
Notes:
1. Operation of this device in excess of any of
these limits may cause permanent damage
2. Source lead temperature is 25° C. Derate 14.9
mW/°C for TL > 130.0° C.
3. Thermal resistance measured using 150° C
Infra-Red Microscopy Technique.
Table 2. MGA-31716 Electrical Specification [1]
TC = 25° C, Vd = 5.0 V, unless otherwise noted
Symbol
Parameter and Test Condition
Frequency
Units
Min.
Typ.
Max.
Ids
Quiescent Current
450 MHz
900 MHz
1500 MHz
mA
37
63
58
54
83
NF
Noise Figure
450 MHz
900 MHz
1500 MHz
dB
–
1.8
1.9
1.8
2.7
Gain
Gain
450 MHz
900 MHz
1500 MHz
dB
18.5
21.0
20.2
19.6
21.5
OIP3 [2, 4]
Output Third Order Intercept Point
450 MHz
900 MHz
1500 MHz
dBm
37
40.5
41.0
41.0
–
LFOM [3]
Linearity Figure of Merit
450 MHz
900 MHz
1500 MHz
dBm
P1dB
Output Power at 1dB Gain Compression
450 MHz
900 MHz
1500 MHz
dBm
PAE
Power Added Efficiency at P1dB
450 MHz
900 MHz
1500 MHz
%
45.3
43.9
42.5
IRL
Input Return Loss
450 MHz
900 MHz
1500 MHz
dB
15.3
16.7
18.7
ORL
Output Return Loss
450 MHz
900 MHz
1500 MHz
dB
13.8
15.9
12.0
ISOL
Isolation
450 MHz
900 MHz
1500 MHz
dB
25.2
25.7
26.7
15.5
16.5
16.8
19.5
22.1
21.2
21.1
–
Notes:
1. Measurements obtained from test circuit and demoboard detailed in Figures 46 and 47 and Table 3.
2. OIP3 test condition: F1 – F2 = 1 MHz, with input power of -12 dBm per tone measured at worst case side band.
3. LFOM is defined as LFOM = OIP3 (in dBm) – PDC (in dBm). It is a measure of the linearity of an amplifier per unit of DC power consumed.
4. Demoboard tuned to best OIP3 with minimum over-temperature drift.
2
MGA-31716 Consistency Distribution Chart [1, 2]
LSL
USL
USL
40
50
60
70
80
Figure 2. Id @ 900 MHz; LSL = 37 mA, Nominal = 58 mA, USL = 83 mA
LSL
1.6
20
21
2.2
2.4
2.6
LSL
36
Figure 4. Gain @ 900 MHz; LSL = 18.5 dB, Nominal = 20.2 dB, USL = 21.5 dB
2
Figure 3. NF @ 900 MHz; Nominal = 1.9 dB, USL = 2.7 dB
USL
19
1.8
38
40
42
44
46
48
50
52
54
56
Figure 5. OIP3 @ 900 MHz; Nominal = 41 dBm, LSL = 37 dBm
LSL
20
21
22
23
24
Figure 6. P1dB @ 900 MHz; Nominal = 21.2 dBm, LSL = 19.5 dBm
Notes:
1. Data sample size is 4000 samples taken from 4 different wafers and 2 different lots. Future wafers allocated to this product may have nominal
values anywhere between the upper and lower limits.
2. Measurements are made on production test board which represents a trade-off between optimal Gain, NF, OIP3 and P1dB. Circuit losses have been
de-embedded from actual measurements.
3
MGA-31716 Typical Performance Data for 450 MHz
TC = 25° C, Vd = 5.0 V, Id = 63 mA (Based on BOM for 450 MHz optimal linearity tuning in Table 3)
42
40
OIP3 (dBm)
OIP3 (dBm)
38
36
34
32
25° C
-40° C
85° C
30
28
-20 -19 -18 -17 -16 -15 -14 -13 -12 -11 -10 -9
Pin (dBm)
-8
-7
Figure 7. OIP3 vs Pin and Temperature
Input Return Loss (dB)
21
Gain (dB)
20
19
18
17
25° C
-40° C
85° C
16
250
350
450
550
Frequency (MHz)
650
750
Figure 9. Gain vs Frequency and Temperature
450
550
Frequency (MHz)
650
750
0
-2
-4
-6
-8
-10
-12
-14
-16
-18
-20
150
25° C
-40° C
85° C
250
350
450
550
Frequency (MHz)
650
750
-10
-25
-26
Isolation (dB)
Output Return Loss (dB)
350
-24
25° C
-40° C
85° C
-5
-15
-20
-27
-28
-25
-29
-30
-30
250
350
450
550
Frequency (MHz)
Figure 11. ORL vs Frequency and Temperature
4
250
Figure 10. IRL vs Frequency and Temperature
0
-35
150
25° C
-40° C
85° C
Figure 8. OIP3 vs Frequency and Temperature
22
15
150
44
42
40
38
36
34
32
30
28
26
24
150
650
750
-31
25° C
-40° C
85° C
150
250
350
450
550
Frequency (MHz)
Figure 12. Isolation vs Frequency and Temperature
650
750
MGA-31716 Typical Performance Data for 450 MHz
TC = 25° C, Vd = 5.0 V, Id = 63 mA (Based on BOM in Table 3, tuned for optimal linearity with over temperature)
23
3.0
22
2.5
Noise Figure (dB)
20
19
18
25° C
-40° C
85° C
17
250
350
450
550
Frequency (MHz)
650
1.0
0.0
150
750
Figure 13. P1dB vs Frequency and Temperature
25° C
-40° C
85° C
250
350
450
550
Frequency (MHz)
25° C
-40° C
85° C
64
40.5
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5
Vd (Volt)
63
62
40.0
61
39.5
39.0
38.5
1000
60
59
OIP3 at R2 = 560 :
Current at R2 = 560 :
1100
1200
1300
R1 (Ohm)
58
1400
Figure 16. OIP3 and Quiescent Current with different R1 [1]
Figure 15. Current vs Voltage and Temperature
41.5
67
41.0
66
65
64
40.0
63
39.5
62
Id (mA)
OIP3 (dBm)
40.5
61
39.0
60
38.5
38.0
470
OIP3 at R1 = 1.2 k:
Current at R1 = 1.2 k:
500
530
560
590
R2 (Ohm)
59
620
650
58
680
Figure 17. OIP3 and Quiescent Current with different R2 [1]
Note:
1. Vbias and Vctrl can be externally controlled by change external biasing resistors R1 = Rbias and R2 = Rctrl (as shown in Fig. 46).
5
750
65
41.0
100
90
80
70
60
50
40
30
20
10
0
650
Figure 14. Noise Figure vs Frequency and Temperature
OIP3 (dBm)
Id (mA)
1.5
0.5
16
150
2.0
57
1500
Id (mA)
P1dB (dBm)
21
MGA-31716 Typical Performance Data for 450 MHz
TC = 25° C, Vd = 5.0 V, Id = 63 mA (Based on BOM in Table 3, tuned for optimal linearity with over temperature)
72
22.2
22.3
72
22.2
71
22.0
22.1
22.0
70
21.9
69
21.9
1000
P1dB at R2 = 560 :
Current at R2 = 560 :
1100
1200
1300
R1 (Ohm)
69
21.8
1400
Figure 18. P1dB and Quiescent Current with different R1 [1]
68
1500
21.7
470
P1dB at R1 = 1.2 k:
Current at R1 = 1.2 k:
500
530
560
590
R2 (Ohm)
620
650
Figure 19. P1dB and Quiescent Current with different R2 [1]
Note:
1. Vbias and Vctrl can be externally controlled by change external biasing resistors R1 = Rbias and R2 = Rctrl (as shown in Fig. 46).
6
68
680
Id (mA)
70
P1dB (dBm)
22.1
Id (mA)
P1dB (dBm)
71
MGA-31716 Typical Performance Data for 900 MHz
TC = 25° C, Vd = 5.0 V, Id = 58 mA (Based on BOM in Table 3, tuned for optimal linearity with over temperature)
42
38
OIP3 (dBm)
OIP3 (dBm)
40
36
34
25° C
-40° C
85° C
32
30
-20 -19 -18 -17 -16 -15 -14 -13 -12 -11 -10 -9
Pin (dBm)
-8
-7
Figure 20. OIP3 vs Pin and Temperature
45
44
43
42
41
40
39
38
37
36
35
34
33
600
25° C
-40° C
85° C
700
800
900
1000
Frequency (MHz)
1100
1200
1100
1200
Figure 21. OIP3 vs Frequency and Temperature
-4
21
-6
19
18
25° C
-40° C
85° C
17
16
600
700
800
900
1000
Frequency (MHz)
1100
-12
-14
-16
-18
-22
600
0
-24
-5
-25
-10
-15
-20
-25
600
25° C
-40° C
85° C
700
25° C
-40° C
85° C
700
800
900
1000
Frequency (MHz)
Figure 23. IRL vs Frequency and Temperature
Isolation (dB)
Output Return Loss (dB)
-8
-10
-20
1200
Figure 22. Gain vs Frequency and Temperature
-26
-27
-28
25° C
-40° C
85° C
-29
800
900
1000
Frequency (MHz)
Figure 24. ORL vs Frequency and Temperature
7
Input Return Loss (dB)
Gain (dB)
20
1100
1200
-30
600
700
800
900
1000
Frequency (MHz)
Figure 25. Isolation vs Frequency and Temperature
1100
1200
MGA-31716 Typical Performance Data for 900 MHz
TC = 25° C, Vd = 5.0 V, Id = 58 mA (Based on BOM in Table 3, tuned for optimal linearity with over temperature)
22.0
3.0
21.5
2.5
Noise Figure (dB)
20.5
20.0
19.5
19.0
25° C
-40° C
85° C
18.5
18.0
600
700
800
900
1000
Frequency (MHz)
1100
25° C
-40° C
85° C
OIP3 (dBm)
Id (mA)
40
30
20
0
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5
Vd (Volt)
800
900
1000
Frequency (MHz)
1100
41.0
63
40.5
61
40.0
59
39.5
57
39.0
55
38.0
1200
OIP3 at R2 = 560 :
Current at R2 = 560 :
1300
1400
1500
1600
R1 (Ohm)
53
1700
62
42.0
61
41.5
60
41.0
59
40.5
58
40.0
57
39.5
56
39.0
Id (mA)
42.5
55
OIP3 at R1 = 1.5 k:
Current at R1 = 1.5 k:
500
530
560
590
R2 (Ohm)
54
620
650
53
680
Figure 30. OIP3 and Quiescent current with different R2 [1]
Note:
1. Vbias and Vctrl can be externally controlled by change external biasing resistors R1 = Rbias and R2 = Rctrl (as shown in Fig. 46).
8
1200
65
Figure 29. OIP3 and Quiescent current with different R1 [1]
Figure 28. Current vs Voltage and Temperature
38.0
470
700
41.5
38.5
10
38.5
25° C
-40° C
85° C
Figure 27. Noise Figure vs Frequency and Temperature
50
OIP3 (dBm)
1.0
0.0
600
1200
80
60
1.5
0.5
Figure 26. P1dB vs Frequency and Temperature
70
2.0
51
1800
Id (mA)
P1dB (dBm)
21.0
MGA-31716 Typical Performance Data for 900 MHz
21.3
68
66
65
21.1
21.0
1200
64
P1dB at R2 = 560 :
Current at R2 = 560 :
1300
1400
1500
1600
R1 (Ohm)
1700
Figure 31. P1dB and Quiescent current with different R1 [1]
63
1800
P1dB (dBm)
21.2
Id (mA)
P1dB (dBm)
67
21.3
67
21.2
66
21.1
65
21.0
64
P1dB at R1 = 1.5 k:
Current at R1 = 1.5 k:
20.9
63
410 440 470 500 530 560 590 620 650 680
R2 (Ohm)
Figure 32. P1dB and Quiescent current with different R2 [1]
Note:
1. Vbias and Vctrl can be externally controlled by change external biasing resistors R1 = Rbias and R2 = Rctrl (as shown in Fig. 46).
9
Id (mA)
TC = 25° C, Vd = 5.0 V, Id = 58 mA (Based on BOM in Table 3, tuned for optimal linearity with over temperature)
MGA-31716 Typical Performance Data for 1500 MHz
TC = 25° C, Vd = 5.0 V, Id = 54 mA (Based on BOM in Table 3, tuned for optimal linearity with over temperature)
46
44
40
OIP3 (dBm)
OIP3 (dBm)
42
38
36
34
25° C
-40° C
85° C
32
30
-20 -19 -18 -17 -16 -15 -14 -13 -12 -11 -10 -9
Pin (dBm)
-8
-7
Figure 33. OIP3 vs Pin and Temperature
-9
20.5
-11
Gain (dB)
19.5
19.0
18.5
18.0
25° C
-40° C
85° C
17.5
1300
1400
1500
1600
Frequency (MHz)
1700
Input Return Loss (dB)
21.0
17.0
1200
25° C
-40° C
85° C
1300
1800
Figure 35. Gain vs Frequency and Temperature
1800
1700
1800
1700
1800
-13
-15
-17
-19
-21
25° C
-40° C
85° C
-23
1200
1300
1400
1500
1600
Frequency (MHz)
-25.5
25° C
-40° C
85° C
-26.0
Isolation (dB)
-5
-10
-26.5
-27.0
-27.5
-15
25° C
-40° C
85° C
-28.0
1300
1400
1500
1600
Frequency (MHz)
Figure 37. ORL vs Frequency and Temperature
10
1700
Figure 36. IRL vs Frequency and Temperature
0
-20
1200
1400
1500
1600
Frequency (MHz)
Figure 34. OIP3 vs Frequency and Temperature
20.0
Output Return Loss (dB)
45
44
43
42
41
40
39
38
37
36
35
34
33
32
1200
1700
1800
-28.5
1200
1300
1400
1500
1600
Frequency (MHz)
Figure 38. Isolation vs Frequency and Temperature
MGA-31716 Typical Performance Data for 1500 MHz
22.0
3.0
21.5
2.5
Noise Figure (dB)
21.0
20.5
20.0
25° C
-40° C
85° C
19.5
19.0
1200
1300
1400
1500
1600
Frequency (MHz)
1700
1.0
0.0
1200
1800
25° C
-40° C
85° C
1300
1400
1500
1600
Frequency (MHz)
1700
43.0
25° C
-40° C
85° C
70
60
42.5
42.0
OIP3 (dBm)
50
40
30
41.5
41.0
40.5
20
40.0
10
39.5
0
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5
Vd (Volt)
55
44.0
54
43.0
53
42.0
52
41.0
51
610
660
710
R2 (Ohm)
1500
1600 1700
R1 (Ohm)
1800
1900
50
OIP3 at R1 = 1.6 k:
Current at R1 = 1.6 k:
560
1400
Id (mA)
45.0
39.0
510
39.0
1300
OIP3 at R2 = 620 :
Current at R2 = 620 :
Figure 42. OIP3 and Quiescent current with different R1 [1]
Figure 41. Current vs Voltage and Temperature
40.0
760
810
49
Figure 43. OIP3 and Quiescent current with different R2 [1]
Note:
1. Vbias and Vctrl can be externally controlled by change external biasing resistors R1 = Rbias and R2 = Rctrl (as shown in Fig. 46).
11
1800
Figure 40. Noise Figure vs Frequency and Temperature
80
Id (mA)
1.5
0.5
Figure 39. P1dB vs Frequency and Temperature
OIP3 (dBm)
2.0
56
55
54
53
52
51
50
49
48
47
46
2000
Id (mA)
P1dB (dBm)
TC = 25° C, Vd = 5.0 V, Id = 54 mA (Based on BOM in Table 3, tuned for optimal linearity with over temperature)
MGA-31716 Typical Performance Data for 1500 MHz
21.3
61
58
21.0
20.9
1300
57
P1dB at R2 = 620 :
Current at R2 = 620 :
1400
1500
1600 1700
R1 (Ohm)
1800
1900
Figure 44. P1dB and Quiescent current with different R1 [1]
56
2000
P1dB (dBm)
P1dB (dBm)
59
21.1
Id (mA)
60
21.2
21.3
61
21.2
60
21.1
59
21.0
58
P1dB at R1 = 1.6 k:
Current at R1 = 1.6 k:
20.9
510
57
560
610
660
710
R2 (Ohm)
760
Figure 45. P1dB and Quiescent current with different R2 [1]
Note:
1. Vbias and Vctrl can be externally controlled by change external biasing resistors R1 = Rbias and R2 = Rctrl (as shown in Fig. 46).
12
810
Id (mA)
TC = 25° C, Vd = 5.0 V, Id = 54 mA (Based on BOM in Table 3, tuned for optimal linearity with over temperature)
VDD
GND
Application Circuit Description and Layout
R1
R2
IN
L1
C11
C12
L2
AVAGO
Technologies
Figure 46. Application Circuit Diagram
RK_v3.0
C3
C2
C1
C15
OUT
C13 C14
QFN3x3
Oct 2010
Figure 47. Demoboard
Table 3. Bill of Materials – Tuned for optimal linearity performance at different frequencies
Description
Optimum linearity
at 450 MHz
Optimum linearity
at 900 MHz
Optimum linearity
at 1500 MHz
Circuit
Symbol
Size
Value
Value
Value
Manufacturer
C2
0402
5 pF
5 pF
1 pF
Murata
C3
0603
2.2 PF
2.2 PF
2.2 PF
Murata
C11
0402
100 pF
100 pF
100 pF
Murata
C13
0402
12 pF
3.3 pF
1.8 pF
Murata
L1
0402
33 nH
8.2 nH
2.4 nH
Murata
L2 [2]
0402
NR
2.4 pF
1 pF
Murata
R1 [1]
0402
1.2 k:
1.5 k:
1.6 k:
KOA
R2 [1]
0402
560 :
560 :
620 :
KOA
Notes:
NR – Not required in actual PCB design
1. R1 and R2 can be varied to bias Vbias and Vctrl which will provide flexibility to have the product operates at desirable Id, LFOM, and OIP3 drift
across temperature also P1dB.
2. Capacitor is used at L2.
50 : 50 :
50 :
Bias
T
Bias
T
Vbias
Bias
T
Vctrl
Vd
Biasing Network
RF out
RF in
Note:
1. Measurements are conducted on 0.010 inch think ROGER 4350.
The input reference plane is at the end of the RFin pin and the
output reference plane is at the end of the RFout pin as shown in
Figure 48.
Figure 48. Circuit to measure de-embedded S-parameters and Noise Parameter in Table 4 and 5.
13
Table 4. MGA-31716 Typical Scattering Parameters
TC = 25° C, Vd = 5.0 V, Id = 58 mA, Zo = 50 : (Data is de-embedded to the RFin & RFout pins on package. Measurements
were made with Bias-Tees at Vd, Vctrl and Vbias in Figure 48)
Freq
GHz
S11
Mag.
S11
dB
S11
Ang.
S21
Mag.
S21
dB
S21
Ang.
S12
Mag.
S12
dB
S12
Ang.
S22
Mag.
S22
dB
S22
Ang.
K Factor
0.10
0.160
-15.9
177.0
12.600
22.0
158.0
0.057
-25.0
-12.8
0.156
-16.1
177.0
1.046
0.20
0.152
-16.4
163.0
12.300
21.8
143.0
0.057
-24.9
-29.7
0.153
-16.3
149.0
1.056
0.30
0.150
-16.5
152.0
12.100
21.7
127.0
0.056
-25.1
-43.3
0.145
-16.8
125.0
1.068
0.40
0.149
-16.5
142.0
12.000
21.6
111.0
0.056
-25.1
-58.6
0.139
-17.2
105.0
1.072
0.50
0.155
-16.2
133.0
11.900
21.5
94.0
0.055
-25.2
-73.0
0.132
-17.6
83.8
1.080
0.60
0.157
-16.1
120.0
11.700
21.4
77.5
0.054
-25.3
-87.4
0.123
-18.2
62.3
1.091
0.70
0.162
-15.8
110.0
11.600
21.3
60.9
0.053
-25.4
-102.0
0.117
-18.6
40.3
1.103
0.80
0.167
-15.5
96.3
11.500
21.2
44.4
0.053
-25.6
-116.0
0.110
-19.2
17.6
1.114
0.90
0.169
-15.4
83.1
11.300
21.1
27.7
0.052
-25.6
-131.0
0.106
-19.5
-6.7
1.124
1.00
0.173
-15.2
68.8
11.200
21.0
11.0
0.052
-25.7
-145.0
0.102
-19.8
-30.1
1.138
1.10
0.177
-15.0
53.4
11.000
20.9
-5.6
0.051
-25.8
-159.0
0.101
-19.9
-52.4
1.150
1.20
0.177
-15.0
37.1
10.900
20.7
-22.2
0.050
-26.0
-174.0
0.100
-20.0
-76.0
1.170
1.30
0.179
-14.9
19.6
10.700
20.6
-39.0
0.049
-26.2
171.0
0.101
-19.9
-97.3
1.186
1.40
0.181
-14.9
0.5
10.600
20.5
-55.7
0.048
-26.3
156.0
0.103
-19.8
-117.0
1.205
1.50
0.181
-14.9
-19.2
10.400
20.4
-72.5
0.047
-26.5
142.0
0.105
-19.6
-136.0
1.227
1.60
0.182
-14.8
-40.2
10.200
20.2
-89.4
0.046
-26.7
127.0
0.107
-19.4
-154.0
1.255
1.70
0.186
-14.6
-63.3
10.100
20.1
-106.0
0.045
-26.9
112.0
0.109
-19.2
-169.0
1.280
1.80
0.190
-14.4
-87.6
9.920
19.9
-124.0
0.045
-27.0
97.0
0.113
-18.9
174.0
1.306
1.90
0.199
-14.0
-113.0
9.720
19.8
-141.0
0.044
-27.2
82.1
0.113
-18.9
160.0
1.338
2.00
0.215
-13.3
-138.0
9.510
19.6
-158.0
0.042
-27.5
66.8
0.117
-18.6
147.0
1.378
2.10
0.235
-12.6
-163.0
9.290
19.4
-176.0
0.041
-27.7
51.4
0.120
-18.4
135.0
1.416
2.20
0.260
-11.7
172.0
9.030
19.1
166.0
0.040
-28.0
35.4
0.124
-18.2
122.0
1.462
2.30
0.293
-10.7
147.0
8.740
18.8
149.0
0.038
-28.4
19.9
0.128
-17.8
112.0
1.518
2.40
0.329
-9.7
123.0
8.430
18.5
131.0
0.036
-28.8
3.6
0.137
-17.3
99.7
1.581
2.50
0.369
-8.7
99.9
8.090
18.2
113.0
0.035
-29.2
-12.9
0.143
-16.9
88.0
1.645
3.00
0.602
-4.4
-5.8
5.990
15.5
22.4
0.026
-31.9
-92.1
0.212
-13.5
24.4
2.073
3.50
0.779
-2.2
-96.4
3.830
11.7
-63.3
0.017
-35.4
-168.0
0.302
-10.4
-45.9
2.787
4.00
0.863
-1.3
-174.0
2.290
7.2
-141.0
0.011
-38.8
124.0
0.381
-8.4
-114.0
4.181
5.00
0.887
-1.1
52.5
0.838
-1.5
80.8
0.007
-42.6
-3.9
0.476
-6.4
121.0
13.380
6.00
0.887
-1.0
-69.8
0.353
-9.1
-45.3
0.007
-42.8
-129.0
0.500
-6.0
3.2
31.411
7.00
0.900
-0.9
173.0
0.159
-16.0
-168.0
0.008
-42.0
111.0
0.526
-5.6
-115.0
54.716
8.00
0.902
-0.9
61.0
0.075
-22.5
72.4
0.008
-41.5
-2.2
0.566
-5.0
131.0
99.527
9.00
0.888
-1.0
-47.5
0.038
-28.3
-49.7
0.009
-40.5
-117.0
0.585
-4.7
22.3
192.476
10.00
0.873
-1.2
-155.0
0.021
-33.5
-175.0
0.010
-40.0
128.0
0.584
-4.7
-88.3
375.167
11.00
0.870
-1.2
95.6
0.014
-37.3
54.6
0.010
-39.8
15.9
0.590
-4.6
159.0
572.555
12.00
0.878
-1.1
-13.8
0.009
-40.5
-75.5
0.009
-40.8
-99.3
0.619
-4.2
44.2
821.109
13.00
0.881
-1.1
-117.0
0.004
-48.3
143.0
0.005
-45.7
130.0
0.684
-3.3
-71.2
2981.617
14.00
0.877
-1.1
146.0
0.011
-39.5
103.0
0.009
-41.1
92.2
0.744
-2.6
180.0
557.304
15.00
0.860
-1.3
45.8
0.006
-44.6
-26.7
0.005
-45.5
-34.7
0.795
-2.0
68.4
1534.771
16.00
0.840
-1.5
-67.3
0.007
-42.8
-46.8
0.007
-43.0
-58.6
0.711
-3.0
-71.0
1428.991
17.00
0.849
-1.4
-178.0
0.013
-38.0
173.0
0.012
-38.3
161.0
0.560
-5.0
165.0
624.270
18.00
0.863
-1.3
86.1
0.013
-37.9
59.9
0.012
-38.2
46.2
0.528
-5.6
75.7
583.097
19.00
0.862
-1.3
-7.0
0.014
-37.0
-48.0
0.014
-37.3
-60.8
0.516
-5.8
-12.9
486.734
20.00
0.839
-1.5
-105.0
0.013
-37.8
-177.0
0.016
-36.0
165.0
0.463
-6.7
-117.0
574.400
14
MGA-31716 Stability
TC = 25° C, Vd = 5.0 V, Id = 58 mA, Zo = 50 : (Data is de-embedded to the RFin & RFout pins. Measurements were made
with Bias-T at Vd, Vctrl and Vbias in Figure 48)
10
9
8
7
6
5
4
3
2
1
0
K Factor
K Factor
0
2
4
6
8
10 12
Frequency (GHz)
14
16
18
20
Figure 49. K-Factor vs Frequency
Table 5. MGA-31716 Typical Noise Parameters
TC = 25° C, Vd = 5.0 V, Id = 58 mA, Zo = 50 : (Data is de-embedded to the RFin & RFout pins on package. Measurements
were made with Bias-Tees at Vd, Vctrl and Vbias in Figure 48)
Freq
(GHz)
Fmin
(dB)
*opt
Mag
*opt
Ang
Rn/Z0
Ga
(dB)
0.5
1.46
0.159
-146.4
0.1272
21.43
0.8
1.55
0.120
-132.4
0.1384
21.22
0.9
1.60
0.105
-129.3
0.1440
21.13
1.0
1.63
0.097
-124.0
0.1546
21.10
1.5
1.74
0.043
-47.2
0.1972
20.43
2.0
1.92
0.168
36.3
0.2498
19.74
2.5
2.24
0.327
78.4
0.2862
18.89
3.0
2.52
0.544
109.3
0.3296
17.89
3.5
2.87
0.672
138.0
0.4130
18.56
4.0
3.38
0.781
159.6
0.5284
15.33
4.5
4.23
0.85
175.2
0.9124
13.18
5.0
5.12
0.881
-163.3
1.4458
11.13
5.5
6.54
0.919
-148.4
2.9438
7.73
6.0
7.84
0.916
-141.4
4.2160
5.92
15
PCB Layout and Stencil Design
2.92
3.20
0.32
Chamfer 0.24
0.50
0.50
Chamfer 0.192
Chamfer 0.06
ø 0.26
0.56
1.24
0.21
1.55
0.23
0.49
0.32
0.35
0.50
1.24
1.55
PCB LAND PATTERN (TOP VIEW)
STENCIL OUTLINE
3.20
0.50
0.50
0.23
1.24
1.55
0.21
0.36
Notes:
1. All dimensions are in milimeters
2. 4mil stencil thickness recommended
16
1.24
1.55
COMBINED PCB & STENCIL LAYOUTS
Package Dimensions
Pin 1 dot
By marking
3.00 ±0.10
1.55 ±0.05
Exp.DAP
0.20 Ref.
Pin #1 identification
Chamfer 0.30 x 45°
0.40 ±0.05
3.00 ±0.10
0.50 Bsc
31716
YYWW
XXXX
1.55 ±0.05
Exp.DAP
0.23 ±0.05
0.00 ±0.05
0.85 ±0.05
TOP VIEW
SIDE VIEW
Notes:
1. All dimensions are in milimeters.
2. Dimensions are inclusive of plating.
3. Dimensions are exclusive of mold flash and metal burr.
Part Number Ordering Information
Part Number
No. of Devices
Container
MGA-31716-BLKG
100
Antistatic Bag
MGA-31716-TR1G
3000
13” Tape/Reel
17
1.50
Ref.
BOTTOM VIEW
Device Orientation
REEL
USER FEED DIRECTION
CARRIER
TAPE
USER
FEED
DIRECTION
31716
YYWW
XXXX
31716
YYWW
XXXX
31716
YYWW
XXXX
TOP VIEW
END VIEW
COVER TAPE
Tape Dimensions
2.0 ± 0.1[1]
0.3 ±0.05
4.0 ±0.1[2]
1.75 ± 0.1
1.55 ±0.05
5.5 ±0.1[1]
CL
3.3 ±0.1
1.6 ± 0.1
12.0 ± 0.3
R 0.3
Typical
1.55 ±0.1
8.0 ±0.1
Notes:
1. Measured from centerline of sprocket hole to centerline of pocket
2. Cumulative tolerance of 10 sprocket holes is ±0.20
3. Other material available
4. All dimensions in millimeter unless otherwise stated
18
3.3±0.1
Reel Dimension – 13” Reel 12 mm Width
11
12 1
2
3
4
0 2
10
9
7
6
5
DATE CODE
12MM
8
EMBOSSED LETTERING
16.0 mm HEIGHT x MIN. 0.4 mm THICK.
Ø329.0±1.0
HUB
Ø100.0±0.5
6
PS
0 2
1
1112 2
3
10
4
9
8 7 6 5
MP
N
CPN
EMBOSSED LETTERING
7.5 mm HEIGHT
EMBOSSED LETTERING
7.5 mm HEIGHT
Ø13.0 +0.5
-0.2
20.2 (MIN.)
(MI
N.)
FRONT VIEW
1.5
EMBOSSED LINE (2x)
89.0 mm LENGTH LINES 147.0 mm
AWAY FROM CENTER POINT
Ø16.0
11.9-15.4**
ESD LOGO
Detail "X"
12.4 +2.0*
-0.0
6
PS
RECYCLE LOGO
SEE DETAIL "X"
Ø100.0±0.5
Ø329.0±1.0
6
PS
SLOT
5.0±0.5 (3x)
R19.0±0.5
Ø12.3±0.5(3x)
BACK VIEW
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18.4 MAX.*
www.avagotech.com
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Data subject to change. Copyright © 2005-2011 Avago Technologies. All rights reserved.
AV02-3264EN - December 8, 2011