BOARDCOM MGA-65606 Low noise amplifi er with switchable bypass/shutdown mode in low profi le package Datasheet

MGA-65606
Low Noise Amplifier with switchable Bypass/Shutdown Mode
in Low Profile Package
Data Sheet
Description
Features
Avago Technologies’ MGA-65606 is an economical, easyto-use GaAs MMIC Low Noise Amplifier (LNA) with Bypass/
Shutdown mode. The LNA has low noise and high linearity
achieved through the use of Avago Technologies’ proprietary 0.25 m GaAs Enhancement-mode pHEMT process.
The Bypass/Shutdown mode enables the LNA to be
bypassed during high input signal power and reduce
current consumption. It is housed in a low profile 2.0 x 1.3
x 0.5 mm3 6-pin Ultra Thin Package. The compact footprint
and low profile coupled with low noise, high linearity make
the MGA-65606 an ideal choice as a low noise amplifier for
mobile and CPE receivers in the WiMAX and WLL (2.5 – 4)
GHz band.
 Low current consumption
Component Image
3.5 GHz; 3V, 10mA (Typ):
2.0 x 1.3 x 0.5 mm3 6-lead Ultra Thin Package
 15.3 dB Gain
Note:
Package marking provides
orientation and identification
“65” = Product Code
“X” = Month Code
65X
 Adjustable bias current
 Simple matching network
 Broadband operation (2.5 – 4) GHz
 Low Noise Figure
 Low current consumption in Bypass Mode, <100 A
 Fully matched to 50 ohm in Bypass Mode
 High Linearity (LNA and Bypass Mode)
 Low profile package
Typical Performance
 1.05 dB Noise Figure
 +5.7 dBm Input IP3
 -2.4 dBm Input Power at 1 dB gain compression
 4.2 dB Insertion Loss in Bypass Mode
 17 dBm IIP3 in Bypass Mode (Pin = -20 dBm)
Pin Configuration
 <100 A current consumption in Bypass mode
Pin 1 (Vbias)
Pin 2 (RFin)
GND
Pin 3 (Gnd)
Pin 6 (Vsd)
Applications
Pin 5 (RFOut)
 Low noise amplifier for WiMAX, Wireless Local Loop.
Pin 4 (Vdd)
 Other ultra low noise applications in the 2.5 – 4 GHz
band.
TOP VIEW
Simplified Schematic
R
Attention: Observe precautions for
handling electrostatic sensitive devices.
ESD Machine Model = 50 V
ESD Human Body Model = 300 V
Refer to Avago Application Note A004R:
Electrostatic Discharge, Damage and Control.
VBias
1
Bias /
Control
6
VSD
L
2
RF IN
5
RF OUT
L
3
LNA
4
L
R
Vdd
C
C
Absolute Maximum Rating [1] TA = 25° C
Thermal Resistance
Symbol
Parameter
Units
Absolute Maximum
Vdd
Device Voltage, RF Output to Ground
V
5
Vbias
Control Voltage
V
(Vdd-0.3)
Pin,max
CW RF Input Power
dBm
+12
Pdiss
Total Power Dissipation
mW
104
Tj
Junction Temperature
°C
150
TSTG
Storage Temperature
°C
-65 to 150
Thermal Resistance [2,3]
(Vdd = 3.0 V, Id = 10 mA),
jc = 80° C/W
Notes:
1. Operation of this device in excess of any of
these limits may cause permanent damage.
2. Thermal resistance measured using Infra-Red
Measurement Technique.
3. Board temperature (Tb) is 25° C, for Tb >146° C,
derate the device power at 14 mW per °C
rise in Board (pakcage belly) temperature.
Product Consistency Distribution charts [1]
USL
LSL
13
14
15
16
USL
17
0.7
Figure 1. Gain @ 3.5 GHz,Vdd 3V; Vbias 2.7 V
LSL = 14 dB, Nominal = 15.3 dB, USL = 17 dB
0.8
0.9
1
1.1
1.2
1.3
1.4
1.5
Figure 2. NF @ 3.5 GHz,Vdd 3 V; Vbias 2.7 V
Nominal = 1.05 dB, USL = 1.35 dB
USL
Note:
1. Distribution data sample size is 3000 samples taken from 3 different
wafers and 3 different lots. Future wafers allocated to this product
may have nominal values anywhere between the upper and lower
limits.
7
8
9
10
Figure 3. Idd @ 3.5 GHz,Vdd 3 V; Vbias 2.7 V
Nominal = 10.0 mA, USL = 12.0 mA
2
11
12
13
Electrical Specifications [1]
TA = 25° C, Vdd =3 V, Vbias = 2.7 V, RF measurement at 3.5 GHz – Typical Performance
Symbol
Parameter and Test Condition
Units
Min.
Typ.
Max.
LNA Mode performance ( Vdd = 3 V,Vbias = 2.7 V & VSD = 0 V)
Idd
Bias Current
mA
–
10
12
Gain
Gain
dB
14
15.3
17
NF
Noise Figure
dB
–
1.05
1.35
IIP3
Input Third Order Intercept Point
dBm
–
+5.7
–
IP1dB
Input Power at 1 dB Gain Compression
dBm
–
-2.4
–
S11
Input Return Loss, 50  source
dB
–
-13.6
–
S22
Output Return Loss, 50  load
dB
–
-11
–
S12
Reverse Isolation
dB
–
-24
–
BYPASS Mode performance ( Vdd = 3 V, Vbias = 0 V & VSD = 0 V)
|S21|BYPASS
Bypass Mode Insertion Loss
dB
–
4.2
–
IIP3BYPASS
Bypass Mode IIP3 (Tested at -20 dBm input Power)
dBm
–
17
–
IddBYPASS
Bypass Mode Current
A
–
70
–
Shutdown Mode performance ( Vdd = 3 V,Vbias = 0 V & VSD = 3 V)
|S21|SHUTDOWN
Shutdown Mode Isolation
dB
–
17
–
IddSHUTDOWN
Shutdown Mode Current
A
–
105
–
Note:
1. 3.5 GHz IIP3 test condition: FRF1 = 3.5 GHz, FRF2 = 3.505 GHz with input power of -20 dBm per tone.
Table 1. LNA Switch Truth Table
Vbias (V) / Vsd (V)
Vdd (V)
Mode
2.7 / 0 [1]
3
LNA
0 / 0 [2]
3
BYPASS
0 / 3 [3]
3
SHUTDOWN
Notes:
1. Device operation in LNA mode if Vbias > 2.2 V and Vsd < 0.5 V. Bias current of LNA can be varied
with different values of Vbias for Vbias > 2.2 V. See Fig 5 below.
2. Device operation in BYPASS mode if Vbias < 0.3 V and VSD < 0.5 V.
3. Device is shutdown if Vsd >2.6 V. In SHUTDOWN mode, LNA and internal Bypass switch is turn
OFF. SHUTDOWN mode override Vbias voltage setting. Pin 6 (Vsd) is a Pull-Down logic function
pin and recommend to ground it if shutdown function is not used in application.
3
Demo Board Layout
GND
Vbias
GND
Vsd
Vdd
GND
1
2
3
4
5
6
MIMOSA v2
GND
Vdd
GND
Vbias
GND
OCT 2010
Avago
Technologies
RF Output
IN
L2
OUT
R2
RF Input
Vsd
L3
L1
C1
R1
C2
Figure 4. Demo Board Layout Diagram
Application Notes
1. Performance in a specified frequency band can be optimized by changing component values in the demo board
above to suit the application at that frequency. The schematic on page 5 show components used to demonstrate
performance at the (3.0 – 4.0) GHz band.
2. Pin1 (Vbias pin) voltage in LNA mode can be varied to enable the LNA bias current to be adjusted, refer to next
graph:
12.0
10.0
Id (mA)
8.0
6.0
4.0
2.0
0.0
2.0
2.1
2.2
2.3
2.4
2.5 2.6
Vbias (V)
2.7
2.8
2.9
Figure 5. Id vs Vbias (Vdd = 3 V; Vsd = 0 V). Vbias is varies in this plot.
4
3.0
Demo Board Schematic for 3.5 GHz application
R2 1
V Bias
(Pin 1)
RF IN
(Pin 2)
6
Bias /
Control
2
50-Ohms TL
VSD
(Pin 6)
L2
5
50-Ohms TL
RF OUT
(Pin 5)
L1
R1
L3
LNA
4
3
C1
C2
Vdd
(Pin 4)
Gnd
(Pin 3)
Figure 6. Demo Board Schematic Diagram
Component
Vendor
Size
Value
L1
Taiyo Yuden
0402
2.2 nH
L2
Taiyo Yuden
0402
2.4 nH
L3
Taiyo Yuden
0402
1.0 nH
C1
Taiyo Yuden
0402
8 pF
C2
Murata
0402
0.1 F
R1
ROHM
0402
10 ohm
R2
ROHM
0402
1.8 Kohm
MGA-65606 Typical Performance (3.5 GHz match)
TA = +25° C, Vdd = 3 V, Ids = 10 mA (Vbias = 2.7 V), RF measurement at 3.5 GHz, Input Signal = CW unless stated
otherwise.
20
10
0
-10
dB
Table 2 Typical Components Used For Demo Board In Fig 4
And Schematic Shown In Fig 6. R2 is adjusted for desired
current.
-20
-30
Input Return Loss
Output Return Loss
Gain
Isolation
-40
-50
-60
1.0
1.5
2.0
2.5
3.0 3.5 4.0
Frequency (GHz)
4.5
5.0
5.5
6.0
Figure 7. LNA Mode Gain, Input Return Loss, Output Return Loss, Isolation vs
Frequency
5
LNA Mode Plots (3.5 GHz match); Vdd = 3 V, Vbias = 2.7 V, Vsd = 0 V
16.0
1.2
15.5
1.1
NF (dB)
Gain (dB)
15.0
14.5
14.0
8 mA
9 mA
10 mA
11 mA
13.5
13.0
3.0
1.0
8 mA
9 mA
10 mA
11 mA
0.9
3.2
3.4
3.6
Frequency (GHz)
3.8
0.8
3.0
4.0
Figure 8. LNA Mode Gain vs Frequency vs Id
3.2
3.4
3.6
Frequency (GHz)
3.8
4.0
Figure 9. LNA Mode Noise Figure vs Frequency vs Id
16.0
1.4
15.5
1.2
NF (dB)
Gain (dB)
15.0
14.5
1.0
0.8
14.0
25° C
85° C
-40° C
13.5
13.0
2.0
2.1
2.2
2.3
2.4
2.5 2.6
Vbias (V)
2.7
2.8
2.9
25° C
85° C
-40° C
0.6
0.4
3.0
Figure 10. LNA Mode Gain vs Vbias vs Temperature
2.0
2.1
2.2
2.3
2.4
2.5 2.6
Vbias (V)
2.7
2.8
2.9
3.0
Figure 11. LNA Noise Figure vs Vbias vs Temperature
-1
8
7
6
IIP3 (dBm)
IP1dB (dBm)
-2
-3
4
-4
25° C
85° C
-40° C
2.0
2.1
2.2
2.3
2.4
2.5 2.6
Vbias (V)
Figure 12. LNA Mode IP1dB vs Vbias vs Temperature
2.7
2.8
2.9
25° C
85° C
-40° C
3
-5
6
5
3.0
2
2.0
2.1
2.2
2.3
2.4
2.5 2.6
Vbias (V)
Figure 13. LNA Mode IIP3 vs Vbias vs Temperature
2.7
2.8
2.9
3.0
LNA Mode Plots (3.5 GHz match); Vdd = 3 V, Vbias = 2.7 V, Vsd = 0 V
Figure 14. Edwards-Sinsky Output Stability Factor(Mu) at Vdd = 3 V
Figure 15. Edwards-Sinsky Input Stability Factor(Mu’) at Vdd = 3 V
Bypass Mode Plots (3.5 GHz match); Vdd = 3 V, Vbias = 0 V, Vsd = 0 V
-3.0
-5
-3.5
Bypass Insertion Loss (dB)
0
-10
dB
-15
-20
-25
Input Return Loss
Output Return Loss
Gain
Isolation
-30
-35
1.5
2.0
2.5
3.0 3.5 4.0 4.5
Frequency (GHz)
5.0
5.5
-5.0
-5.5
-6.0
6.0
Figure 16. Bypass Mode Gain, Input Return Loss, Output Return Loss,
Isolation vs Frequency
3.0
IIP3 (dBm)
20
15
10
25° C
85° C
-40° C
5
3.0
3.2
3.4
3.6
Frequency (GHz)
Figure 18. Bypass Mode IIP3 vs Frequency vs Temperature
3.8
3.2
3.4
3.6
Frequency (GHz)
3.8
4.0
Figure 17. Bypass Mode Insertion Loss vs Frequency vs Temperature
25
IIP3 (dBm)
-4.5
-7.0
1.0
7
-4.0
-6.5
-40
0
25° C
85° C
-40° C
4.0
20
18
16
14
12
10
8
6
4
2
0
-20
-15
-10
-5
Pin (dBm)
Figure 19. Bypass Mode IIP3 vs Input Power
0
5
Shutdown Mode Plots (3.5 GHz match); Vdd = 3 V, Vbias = 0 V, Vsd = 3 V
-12
-10
-14
Shutdown Isolation (dB)
0
dB
-20
-30
-40
Input Return Loss
Output Return Loss
Gain
Isolation
-50
1.5
2.0
2.5
3.0 3.5 4.0
Frequency (GHz)
4.5
-16
-18
-20
-22
-24
3.0
-60
1.0
25° C
85° C
-40° C
5.0
5.5
6.0
Figure 20. Shutdown Mode Gain, Input Return Loss, Output Return Loss,
Isolation vs Frequency
3.2
3.4
3.6
Frequency (GHz)
Figure 21. Shutdown Mode Isolation vs Frequency vs Temperature
Test Circuit For S and Noise parameter measurement [1] (3.5GHz match)
Reference plane
MGA-65606
V Bias
(Pin 1)
RF IN
(Pin 2)
R2 1
6
Bias
Bias//
Control
Control
2
VSD
(Pin 6)
RF OUT
(Pin 5)
5
R1
L3
LNA
3
C1
Gnd
(Pin 3)
Note:
1. The measurement is calibrated up to the input (RFin) and output (RFout) pin of the package.
Vendor
Size
Value
L3
Taiyo Yuden
0402
1.0 nH
C1
Taiyo Yuden
0402
8 pF
C2
Murata
0402
0.1 F
R1
ROHM
0402
10 ohm
Figure 22. S-parameter and Noise parameter test circuit on demo board
8
Vdd
(Pin 4)
4
Component
3.8
C2
4.0
MGA-65606 LNA Mode typical scattering parameters at 25° C, Vdd = 3 V; Vbias = 2.7 V; Vsd = 0 V
Frequency
(GHz)
S11
Mag
Angle
dB
Mag
Angle
dB
Mag
Angle
Mag
Angle
0.5
0.946
-20.4
-10.90
0.285
-99.4
-66.08
0.000
129.5
0.981
-16.1
1.0
0.875
-37.4
-3.43
0.674
-133.6
-59.90
0.001
147.1
0.953
-30.6
1.5
0.816
-50.2
-2.20
0.776
-134.9
-53.80
0.002
177.2
0.944
-45.8
2.0
0.789
-63.4
4.41
1.661
-127.2
-43.11
0.007
-152.1
0.891
-72.4
2.1
0.784
-66.9
6.30
2.065
-131.8
-40.37
0.010
-153.6
0.855
-80.6
2.2
0.777
-70.7
8.08
2.535
-138.7
-37.77
0.013
-158.0
0.802
-90.5
2.3
0.765
-74.9
9.69
3.051
-147.5
-35.45
0.017
-164.8
0.727
-102.9
2.4
0.747
-79.4
11.09
3.587
-157.7
-33.35
0.022
-172.9
0.635
-119.0
2.5
0.723
-84.0
12.28
4.109
-169.0
-31.56
0.026
177.9
0.551
-140.1
2.6
0.694
-88.5
13.22
4.583
179.0
-30.05
0.031
167.9
0.491
-164.7
2.7
0.661
-92.9
13.93
4.971
166.5
-28.80
0.036
157.4
0.450
169.0
2.8
0.626
-97.0
14.40
5.247
153.9
-27.82
0.041
146.7
0.422
141.8
2.9
0.591
-100.7
14.64
5.396
141.4
-27.10
0.044
136.2
0.404
114.5
3.0
0.556
-104.0
14.68
5.417
129.3
-26.60
0.047
126.1
0.395
87.7
3.5
0.442
-114.0
12.88
4.406
81.3
-26.28
0.049
87.8
0.553
-13.1
4.0
0.419
-121.3
10.58
3.380
51.2
-26.77
0.046
67.4
0.704
-49.3
4.5
0.419
-128.3
8.74
2.735
29.3
-27.01
0.045
55.5
0.771
-70.9
5.0
0.415
-135.7
7.12
2.271
10.4
-27.11
0.044
47.0
0.815
-89.8
5.5
0.423
-144.2
5.70
1.927
-7.2
-27.08
0.044
40.1
0.842
-106.6
6.0
0.444
-151.5
4.56
1.690
-22.9
-26.77
0.046
35.4
0.855
-119.0
6.5
0.452
-158.2
3.52
1.499
-37.7
-26.31
0.048
31.7
0.863
-131.5
7.0
0.450
-165.6
2.54
1.340
-52.3
-25.70
0.052
28.4
0.867
-144.9
7.5
0.448
-174.7
1.52
1.192
-66.9
-24.98
0.056
24.9
0.869
-159.6
8.0
0.460
174.6
0.37
1.044
-81.6
-24.28
0.061
20.7
0.868
-175.2
8.5
0.492
163.8
-0.97
0.894
-96.4
-23.67
0.066
15.8
0.868
169.1
9.0
0.539
154.2
-2.57
0.744
-110.8
-23.19
0.069
10.7
0.869
154.4
9.5
0.592
146.0
-4.42
0.601
-123.5
-22.75
0.073
5.7
0.865
141.7
10.0
0.637
138.5
-6.14
0.493
-135.1
-22.43
0.076
0.1
0.863
132.4
9
S21
S12
S22
MGA-65606 Bypass Mode typical scattering parameters at 25° C, Vdd = 3 V; Vbias = 0 V; Vsd = 0 V
Frequency
(GHz)
S11
Mag
Angle
dB
Mag
Angle
dB
Mag
Angle
Mag
Angle
0.5
0.896
-36.0
-40.99
0.009
161.7
-39.91
0.010
147.7
0.980
-16.1
1.0
0.784
-65.2
-26.78
0.046
127.6
-26.74
0.046
128.0
0.953
-30.3
1.5
0.648
-94.0
-21.33
0.086
125.1
-21.30
0.086
125.4
0.930
-45.7
2.0
0.353
-103.4
-12.00
0.251
116.6
-11.96
0.252
116.9
0.738
-65.0
2.1
0.334
-100.3
-10.12
0.312
107.7
-10.08
0.313
108.0
0.683
-66.6
2.2
0.325
-97.4
-8.56
0.373
96.9
-8.52
0.375
97.2
0.635
-67.2
2.3
0.321
-94.5
-7.34
0.430
85.2
-7.30
0.432
85.5
0.595
-67.1
2.4
0.325
-91.6
-6.45
0.476
73.1
-6.41
0.478
73.3
0.564
-66.4
2.5
0.338
-88.6
-5.87
0.509
61.1
-5.83
0.511
61.4
0.541
-65.4
2.6
0.366
-85.9
-5.55
0.528
49.7
-5.51
0.530
50.0
0.526
-64.0
2.7
0.419
-85.4
-5.44
0.535
39.1
-5.40
0.537
39.3
0.521
-62.4
2.8
0.483
-89.8
-5.48
0.532
29.5
-5.44
0.534
29.7
0.528
-61.1
2.9
0.531
-96.6
-5.62
0.523
20.8
-5.58
0.526
21.1
0.544
-60.6
3.0
0.562
-103.5
-5.82
0.512
13.1
-5.78
0.514
13.4
0.567
-61.2
3.5
0.626
-132.3
-6.96
0.449
-16.4
-6.92
0.451
-16.1
0.661
-74.8
4.0
0.649
-152.8
-7.99
0.398
-37.9
-7.95
0.400
-37.7
0.708
-91.6
4.5
0.656
-168.2
-8.84
0.361
-55.3
-8.80
0.363
-55.0
0.734
-106.1
5.0
0.660
178.6
-9.76
0.325
-70.9
-9.72
0.327
-70.7
0.754
-120.1
5.5
0.665
167.2
-10.73
0.291
-85.7
-10.69
0.292
-85.5
0.766
-133.9
6.0
0.660
157.2
-11.52
0.265
-99.6
-11.48
0.267
-99.3
0.763
-145.6
6.5
0.650
147.3
-12.38
0.240
-113.8
-12.34
0.242
-113.5
0.757
-157.3
7.0
0.651
137.3
-13.46
0.212
-128.8
-13.42
0.213
-128.5
0.749
-169.6
7.5
0.677
127.8
-14.98
0.178
-145.2
-14.93
0.179
-144.9
0.741
177.2
8.0
0.733
119.6
-17.19
0.138
-163.0
-17.15
0.139
-162.7
0.734
163.4
8.5
0.810
112.1
-20.50
0.094
177.4
-20.45
0.095
177.7
0.732
150.0
9.0
0.881
104.2
-25.53
0.053
154.0
-25.47
0.053
154.3
0.737
138.2
9.5
0.922
95.4
-32.57
0.024
110.0
-32.47
0.024
110.3
0.746
128.5
10.0
0.924
85.9
-36.06
0.016
45.3
-35.99
0.016
45.7
0.756
121.6
10
S21
S12
S22
MGA-65606 LNA Mode typical noise parameters at 25° C, Vdd = 3 V; Vbias = 2.7 V; Vsd = 0 V
Freq. (GHz)
Fmin (dB)
opt Mag
opt Ang
Rn/50
2.0
0.79
0.36
41.93
0.09
2.1
0.76
0.36
44.59
0.11
2.2
0.73
0.36
47.26
0.13
2.3
0.71
0.36
49.93
0.15
2.4
0.70
0.36
52.59
0.16
2.5
0.70
0.36
55.26
0.18
2.6
0.71
0.36
57.93
0.19
2.7
0.73
0.36
60.60
0.20
2.8
0.75
0.36
63.26
0.21
2.9
0.78
0.36
65.93
0.22
3.0
0.81
0.36
68.60
0.22
3.1
0.85
0.36
71.27
0.22
3.2
0.89
0.36
73.93
0.23
3.3
0.94
0.36
76.60
0.22
3.4
0.99
0.36
79.27
0.22
3.5
1.05
0.36
81.94
0.22
3.6
1.08
0.35
84.60
0.21
3.7
1.13
0.35
87.27
0.21
3.8
1.18
0.35
89.94
0.20
3.9
1.23
0.35
92.60
0.19
4.0
1.28
0.35
95.27
0.18
4.2
1.36
0.35
100.60
0.16
4.4
1.43
0.35
105.90
0.14
4.6
1.47
0.35
111.30
0.12
4.8
1.49
0.35
116.60
0.10
5.0
1.48
0.35
121.90
0.08
5.2
1.42
0.35
127.30
0.06
5.4
1.33
0.35
132.60
0.05
5.6
1.18
0.35
137.90
0.04
5.8
0.97
0.35
143.30
0.03
6.0
0.71
0.35
148.60
0.03
11
Package Dimensions
Pin#1 DOT by Marking
Pin#1 Indicator
R0.10
0.50 ±0.05
2.00 ±0.05
1.10
0.50
1.30 ±0.05
65X
1.10
0.20
0.25
SIDE VIEW
TOP VIEW
BOTTOM VIEW
Notes:
1. All dimensions are in milimeters.
2. Dimensions are inclusive of plating.
3. Dimensions are exclusive of mold flash and metal burr.
PCB Land Patterns and Stencil Design
1.70
1.10
0.435
1.70
1.10
0.386 sq.
0.286 sq.
0.26 sq.
0.30
0.50
R0.10
0.510
0.31
0.23
1.30
0.332
0.23
LAND PATTERN WITH VIA
0.31
0.50
0.445
0.35
STENCIL OPENING
1.70
Top Metal
1.10
Solder Mask Opening
0.286 sq.
0.26 sq.
0.50
0.23
0.31
Notes:
1. All dimension are in mm.
2. Recommend to use standard 4 mils Stencil thickness.
COMBINED LAND PATTERN & STENCIL OPENING
12
Device Orientation
REEL
USER FEED DIRECTION
65X
CARRIER
TAPE
USER
FEED
DIRECTION
65X
TOP VIEW
COVER TAPE
Tape Dimensions
Ø 1.50 ±0.10
2.00 ±0.05
4.00 ±0.10
1.75 ±0.10
3.50 ±0.05
+0.30
8.00 0.10
+0.05
4.00 ±0.10
Ø 0.50 0.10
0.20
0.20 ± 0.15
45° MAX.
45° MAX.
0.73 ± 0.05
2.17 ± 0.05
Ao
Ko
(all dimensions in mm)
Part Number Ordering Information
Part #
Qty
Container
MGA-65606-BLKG
100
Antistatic Bag
MGA-65606-TR1G
3000
7” Reel
MGA-65606-TR2G
10000
13” Reel
13
1.67 ± 0.05
Bo
65X
END VIEW
Reel 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 in the United States and other countries.
Data subject to change. Copyright © 2005-2011 Avago Technologies. All rights reserved.
AV02-2889EN - November 15, 2011