AVAGO AMMC-5025 30khz â 80 ghz twa Datasheet

AMMC-5025
30KHz – 80 GHz TWA
Data Sheet
Description
Features
The AMMC-5025 MMIC is a 30KHz to 80GHz ultra broadband traveling wave amplifier. In this operational
frequency band, AMMC-5025 provides 8dB gain with
better than 10dB input and output return losses. This
performance is suitable for instrumentation and high
speed digital communications.
x 50 : match on input and output
Component Image
x ESD protection, 70V MM and 300V HBM
Typical Performance (Vd=5V, Idsq=0.1A)
x Frequency range 30KHz to 80 GHz
x Small signal Gain: 8dB
x P-1dB: 15 dBm @ 40 GHz
x Input/Output return loss of -10dB/-10dB
Applications
x Microwave Radio systems
x Satellite VSAT, Up/Down Link
x Optical fiber laser driver
Chip Size: 1600 x 950 Pm (63 x 37 mils)
Chip Size Tolerance: ± 10 Pm (±0.4 mils)
Chip Thickness: 100 ± 10 Pm (4 ± 0.4 mils)
Pad Dimensions: 75 x 75 Pm (3 x 3 ± 0.4 mils)
Note:
1. This MMIC uses depletion mode pHEMT devices. Negative supply is
used for DC gate biasing.
Attention: Observe Precautions for
handling electrostatic sensitive devices.
ESD Machine Model (Class A): 70V
ESD Human Body Model (Class 1A): 300V
Refer to Avago Application Note A004R:
Electrostatic Discharge Damage and Control.
Absolute Maximum Ratings[1,2,3, and 4]
Symbol
Parameters
Vd
Positive Supply Voltage[2]
Unit
Max
V
7
Vg1
Gate Supply Voltage
V
-3.6 to 0
Vg2
Gate Supply Voltage
V
-2.5 to +2.5
PD
Power Dissipation[2]
W
0.8
Pin
CW Input Power
dBm
23
Tch
Operating Channel Temp.
°C
+150
Tstg
Storage Case Temp.
°C
-65 to +155
Tmax
Maximum Assembly Temp (30 sec max)
°C
+320
Notes:
1. Operation in excess of any one of these conditions may result in permanent damage to this device.
2. Combinations of supply voltage and drain current shall not exceed PD.
3. The operating channel temperature will directly affect the device MTTF. For maximum life, it is recommended that junction temperatures be
maintained at the lowest possible levels.
DC Specifications/ Physical Properties [5]
Symbol
Parameters and Test Conditions
Unit
Min
Typ
Vd
Drain Supply Voltage
V
5
Id(q)
Drain Supply Current (Vd=5 V, Vg set for Id(q)Typical)
mA
100
Vg1
Gate Supply Operating Voltage (Id(q) = 100 mA)
V
-3.6
-2.0
-1.2
-2.5
+1.2
+2.5
Vg2
Gain control voltage. Open on the Vg2 makes highest gain.
V
RTjc
Thermal Resistance[5] (Channel-to-Backside)
°C/W
12.8
Tch
Channel Temperature @85°C Backside
°C
91.4
Max
RF Specifications [1,2]
TA= 25°C, Vdd = 5 V, Idq =0.1 A, Zo=50 :
Symbol
Parameters and Test Conditions
Units
Minimum
Freq
Operational Frequency
GHz
30KHz
Gain
Small-signal Gain Freq = 2, 10, 20, 30, 40 GHz
dB
7.5
8
P-1dB
Output Power at 1dB Gain Compression Freq = 40GHz
dBm
13
15
OIP3
Third Order Output Intercept Point@20GHz 'f = 10MHz,
Po = +10dBm, SCL
dBm
20
RLin
Input Return Loss
dB
10
RLout
Output Return Loss
dB
15
Isolation
Reverse Isolation
dB
27
Notes:
1. Small/Large -signal data measured from an on-wafer tester at TA = 25°C.
2. 100% on-wafer RF test of Gain, Return Losses and Reverse Isolation is done at frequencies: 2,10, 20, 30, and 40 GHz.
2
Typical
Maximum
80
Typical Performance (Data obtained from on-wafer condition)
(TA = 25°C, Vdd = 5V, Idq = 0.1A, Vg = -1.8 V, Zin = Zout = 50 :)
14
S11 (dB)
S22 (dB)
-10
-20
8
-30
6
-40
4
-50
2
-60
0
-5
Return Loss (dB)
10
S12 (dB)
-15
-20
-70
0
20
40
60
Frequency (GHz)
80
0
100
Figure 1. Typical Gain and Reverse Isolation
80
100
0.2
Pout (dBm)
PAE (%)
Id (total)
20
Po (dBm), PAE (%)
P-1 and P-3 (dBm)
40
60
Frequency (GHz)
25
P-1
P-3
18
16
14
12
15
0.1
10
5
0
0
10
20
30
40
50
Frequency (GHz)
Figure 3. Typical Output Power vs. Frequency
3
20
Figure 2. Typical Return Loss (Input and Output)
20
10
-10
Ids (A)
12
S21 (dB)
0
0
S21 (dB)
S12 (dB)
60
70
80
-5
-15
0
-10
-5
0
Pin (dBm)
5
10
15
Figure 4. Typical Output Power, PAE, and Total Drain Current versus Input
Power at 50GHz
Typical Bias Dependency (Data obtained from on-wafer condition)
(TA = 25°C, Vdd = 5V, Zin = Zout = 50 :)
14
12
8
S22 (dB)
Gain (dB)
10
6
4
Ids=120mA
Ids=100mA
Ids=80mA
2
0
0
20
40
60
Frequency (GHz)
80
100
0
-2
-4
-6
-8
-10
-12
-14
-16
-18
-20
20
40
60
Frequency (GHz)
Figure 7. Typical S11 bias dependency at Vds=5V
4
20
40
60
Frequency (GHz)
80
100
Figure 6. Typical S22 bias dependency at Vds=5V
Ids=120mA
Ids=100mA
Ids=80mA
0
Ids=120mA
Ids=100mA
Ids=80mA
0
Gain (dB)
S11 (dB)
Figure 5. Typical Gain bias dependency at Vds=5V
0
-2
-4
-6
-8
-10
-12
-14
-16
-18
-20
80
100
20
10
0
-10
-20
-30
-40
-50
-60
-70
-80
Vg2=2.5V
Vg2=1.5V
Vg2=0.5V
Vg2=-0.5V
Vg2=-1.5V
0
20
Vg2=2V
Vg2=1V
Vg2=0V
Vg2=-1V
Vg2=-2V
40
60
Frequency (GHz)
Figure 8. Gain control using Vg2 voltage at Vds=5V
80
100
AMMC-5025 Performance Distributions Sample Size= 6,876
P1dB (Freq=20GHz)
16
S21 (Freq=20 GHz)
17
18
7.7
7.9
(dBm)
-29
-27
-25
-23
(dB)
5
8.3
8.5
8.7
8.9
9.1
(dB)
S11 (Freq=20 GHz)
-31
8.1
S22 (Freq=20 GHz)
-21
-19
-17
-17
-16
(dB)
-15
Typical Scattering Parameters [1], (TA = 25°C, Vd =5 V, ID = 0.1 A, Zin = Zout = 50 :)
Freq
[GHz]
S11
dB
Mag
Phase
dB
Mag
Phase
dB
Mag
Phase
dB
Mag
Phase
1
-23.99
0.06
-73.62
12.31
4.12
145.45
-69.87
3.21E-04
-56.06
-14.28
0.19
-96.92
2
-18.65
0.12
-94.96
11.73
3.86
125.95
-62.19
7.77E-04
42.58
-17.44
0.13
-116.92
3
-15.45
0.17
-108.86
11.44
3.73
103.10
-60.07
9.92E-04
16.73
-17.83
0.13
-125.57
4
-13.42
0.21
-119.17
11.21
3.64
80.66
-59.29
1.09E-03
13.76
-17.20
0.14
-130.80
5
-12.03
0.25
-129.52
10.89
3.50
56.99
-56.48
1.50E-03
9.53
-16.28
0.15
-137.14
6
-11.11
0.28
-139.24
10.41
3.31
35.49
-58.61
1.17E-03
-9.71
-15.61
0.17
-145.25
7
-10.58
0.30
-148.77
9.69
3.05
14.16
-55.23
1.73E-03
-35.56
-14.78
0.18
-152.92
8
-10.23
0.31
-156.02
9.22
2.89
-6.61
-53.10
2.21E-03
-56.51
-14.69
0.18
-160.55
9
-10.00
0.32
-164.67
8.76
2.74
-28.44
-52.66
2.33E-03
-87.14
-14.65
0.19
-170.92
10
-9.98
0.32
-171.35
8.34
2.61
-48.35
-54.79
1.82E-03
-98.55
-15.23
0.17
178.16
11
-10.27
0.31
-177.66
8.34
2.61
-68.27
-50.71
2.91E-03
-101.79
-16.28
0.15
168.15
12
-10.64
0.29
176.54
8.16
2.56
-89.02
-53.25
2.17E-03
-116.45
-18.10
0.12
161.44
13
-11.41
0.27
171.28
8.29
2.60
-107.30
-51.39
2.69E-03
-130.97
-21.07
0.09
154.55
14
-12.43
0.24
166.56
8.44
2.64
-126.33
-49.01
3.54E-03
-138.45
-24.75
0.06
158.47
15
-13.75
0.21
163.42
8.47
2.65
-145.14
-47.72
4.11E-03
-158.18
-29.78
0.03
-153.13
16
-15.13
0.18
159.33
8.44
2.64
-166.53
-45.17
5.51E-03
175.62
-25.88
0.05
-123.66
17
-16.59
0.15
162.90
8.69
2.72
171.17
-44.82
5.74E-03
155.52
-20.77
0.09
-117.97
18
-18.59
0.12
171.69
8.71
2.73
150.24
-43.32
6.82E-03
135.56
-17.99
0.13
-120.53
19
-19.95
0.10
-173.49
8.76
2.74
128.84
-43.20
6.92E-03
111.61
-16.53
0.15
-125.92
20
-19.18
0.11
-154.71
8.68
2.72
106.41
-42.05
7.90E-03
89.64
-15.05
0.18
-134.47
21
-17.62
0.13
-142.23
8.65
2.71
85.73
-42.14
7.81E-03
74.32
-14.45
0.19
-142.80
22
-16.19
0.16
-138.96
9.07
2.84
64.35
-40.01
9.99E-03
57.07
-14.44
0.19
-151.66
23
-14.50
0.19
-140.00
8.53
2.67
40.98
-41.72
8.20E-03
30.87
-14.17
0.20
-159.25
24
-13.26
0.22
-141.73
8.44
2.64
19.92
-42.21
7.75E-03
10.66
-14.57
0.19
-163.44
25
-12.24
0.24
-143.90
8.82
2.76
-1.95
-41.31
8.60E-03
-12.92
-15.12
0.18
-170.40
26
-11.92
0.25
-149.24
8.11
2.54
-24.68
-38.31
1.21E-02
-33.09
-16.15
0.16
-177.73
27
-11.27
0.27
-153.35
8.41
2.63
-46.27
-39.03
1.12E-02
-49.00
-17.25
0.14
-177.36
28
-11.34
0.27
-158.37
8.60
2.69
-65.32
-41.74
8.18E-03
-51.65
-18.78
0.12
174.70
29
-11.23
0.27
-162.71
8.47
2.65
-86.91
-38.69
1.16E-02
-67.54
-20.71
0.09
178.70
30
-11.19
0.28
-168.87
8.31
2.60
-108.37
-36.72
1.46E-02
-98.62
-21.14
0.09
-178.81
31
-11.17
0.28
-171.85
8.36
2.62
-131.62
-36.29
1.53E-02
-116.44
-21.06
0.09
-173.56
32
-11.71
0.26
-178.55
8.38
2.62
-153.01
-34.84
1.81E-02
-144.42
-21.44
0.08
-167.22
33
-12.31
0.24
177.15
8.23
2.58
-174.09
-35.81
1.62E-02
-169.49
-23.56
0.07
-164.19
34
-12.39
0.24
178.75
8.21
2.57
164.71
-35.30
1.72E-02
162.06
-19.46
0.11
-143.08
35
-14.33
0.19
178.41
8.15
2.56
142.95
-33.65
2.08E-02
153.31
-20.37
0.10
-135.61
36
-14.63
0.19
174.11
8.13
2.55
120.78
-35.22
1.73E-02
134.39
-17.53
0.13
-144.76
37
-15.66
0.16
179.07
8.20
2.57
99.36
-33.96
2.01E-02
110.88
-17.39
0.13
-144.66
38
-17.38
0.14
-172.55
8.09
2.54
79.99
-33.63
2.08E-02
86.39
-18.34
0.12
-143.70
39
-17.73
0.13
175.32
8.33
2.61
56.48
-32.90
2.26E-02
75.36
-15.50
0.17
-168.59
40
-16.72
0.15
-162.20
7.98
2.51
35.53
-32.53
2.36E-02
44.17
-16.92
0.14
-160.05
41
-17.01
0.14
-159.26
7.77
2.45
14.46
-31.99
2.52E-02
28.89
-17.35
0.14
-174.76
6
S21
S12
S22
Typical Scattering Parameters [1], (Continued)
Freq
[GHz]
S11
dB
Mag
Phase
dB
Mag
Phase
42
-15.50
0.17
-158.31
7.61
2.40
-8.30
-33.42
2.13E-02
-0.50
-16.97
0.14
179.67
43
-14.80
0.18
-153.02
7.73
2.44
-34.27
-31.12
2.78E-02
-20.36
-17.73
0.13
-175.55
44
-14.68
0.18
-140.97
7.52
2.38
-53.64
-34.84
1.81E-02
8.78
-22.75
0.07
146.52
45
-13.31
0.22
-154.87
7.61
2.40
-74.69
-32.76
2.30E-02
-15.11
-20.52
0.09
171.71
46
-13.20
0.22
-149.60
7.70
2.43
-97.71
-32.73
2.31E-02
-55.67
-22.30
0.08
140.76
47
-13.40
0.21
-157.37
7.67
2.42
-119.57
-32.12
2.48E-02
-93.36
-25.95
0.05
169.29
48
-12.76
0.23
-164.27
7.69
2.42
-141.65
-30.78
2.89E-02
-99.61
-24.46
0.06
147.05
49
-12.35
0.24
-165.03
7.82
2.46
-164.67
-30.54
2.97E-02
-131.38
-34.20
0.02
159.74
50
-12.98
0.22
-178.67
7.81
2.46
172.08
-29.89
3.20E-02
-156.76
-25.26
0.05
175.77
51
-12.51
0.24
-173.74
7.83
2.46
149.86
-30.18
3.10E-02
-178.78
-33.52
0.02
-130.51
52
-13.61
0.21
-172.01
7.93
2.49
128.77
-28.27
3.86E-02
171.08
-31.57
0.03
-115.78
53
-13.92
0.20
177.60
7.77
2.45
105.87
-29.13
3.50E-02
136.16
-23.15
0.07
-132.42
54
-12.94
0.23
-179.13
7.71
2.43
80.50
-28.55
3.74E-02
109.76
-21.67
0.08
-114.64
55
-14.85
0.18
-177.74
8.22
2.58
58.11
-28.87
3.60E-02
93.24
-21.71
0.08
-147.76
56
-14.00
0.20
-172.76
8.41
2.63
37.15
-27.83
4.06E-02
73.29
-17.35
0.14
-132.07
57
-13.98
0.20
-174.58
8.12
2.55
13.47
-28.94
3.57E-02
40.39
-20.62
0.09
-128.62
58
-17.56
0.13
-164.98
8.39
2.63
-6.90
-28.90
3.59E-02
29.47
-18.73
0.12
168.41
59
-13.68
0.21
178.77
7.77
2.45
-31.83
-26.85
4.54E-02
7.31
-19.77
0.10
170.62
60
-17.29
0.14
-162.12
7.79
2.45
-54.89
-32.45
2.38E-02
-9.89
-19.16
0.11
139.41
61
-12.46
0.24
-178.85
8.33
2.61
-80.24
-29.70
3.27E-02
-42.64
-19.72
0.10
134.43
62
-15.19
0.17
-173.34
8.05
2.53
-103.95
-33.29
2.17E-02
-71.74
-19.74
0.10
89.74
63
-12.41
0.24
-161.80
7.96
2.50
-130.10
-28.76
3.65E-02
-71.24
-16.99
0.14
61.67
64
-14.96
0.18
162.01
7.90
2.48
-152.97
-30.55
2.97E-02
-92.14
-24.01
0.06
75.15
65
-10.79
0.29
-154.54
8.43
2.64
-177.52
-29.94
3.19E-02
-126.69
-12.03
0.25
32.27
66
-14.34
0.19
158.99
7.94
2.49
159.47
-29.50
3.35E-02
-150.30
-20.43
0.10
76.21
67
-13.08
0.22
-134.82
8.11
2.54
131.55
-26.52
4.72E-02
177.09
-18.80
0.11
-51.51
68
-12.81
0.23
-173.73
8.69
2.72
107.29
-27.56
4.19E-02
158.17
-20.56
0.09
-43.17
69
-14.26
0.19
172.94
8.37
2.62
83.04
-27.65
4.15E-02
123.32
-24.54
0.06
-140.20
70
-16.20
0.15
-173.41
8.64
2.70
58.43
-28.20
3.89E-02
104.25
-19.68
0.10
-124.67
71
-11.56
0.26
-171.73
8.08
2.54
26.64
-26.98
4.48E-02
86.83
-21.32
0.09
178.78
72
-18.26
0.12
126.51
8.35
2.62
2.92
-28.07
3.95E-02
62.28
-18.15
0.12
136.89
73
-11.30
0.27
172.49
7.98
2.51
-24.03
-27.77
4.09E-02
36.07
-17.75
0.13
96.33
74
-14.30
0.19
-169.17
8.07
2.53
-51.96
-27.62
4.16E-02
17.47
-15.45
0.17
58.31
75
-15.13
0.18
160.81
7.34
2.33
-80.22
-27.46
4.24E-02
-7.47
-13.49
0.21
23.56
76
-12.17
0.25
170.35
7.64
2.41
-108.51
-27.29
4.32E-02
-31.56
-12.78
0.23
20.08
77
-11.84
0.26
-175.68
7.92
2.49
-137.63
-27.16
4.39E-02
-55.43
-12.98
0.22
8.02
78
-12.45
0.24
164.14
7.22
2.30
-166.12
-27.09
4.42E-02
-72.41
-11.83
0.26
-20.15
79
-14.60
0.19
157.52
7.11
2.27
165.62
-26.96
4.49E-02
-99.83
-13.06
0.22
-30.35
80
-12.21
0.25
147.32
7.73
2.43
133.90
-27.24
4.34E-02
-124.77
-17.30
0.14
-25.89
81
-12.46
0.24
159.37
7.77
2.45
106.11
-27.48
4.23E-02
-155.86
-28.28
0.04
-30.33
82
-14.32
0.19
161.28
8.14
2.55
74.42
-28.06
3.96E-02
173.77
-17.84
0.13
60.41
7
S21
S12
dB
S22
Mag
Phase
dB
Mag
Phase
Typical Scattering Parameters [1], (Continued)
Freq
[GHz]
S11
S21
S12
S22
dB
Mag
Phase
dB
Mag
Phase
dB
Mag
Phase
dB
Mag
Phase
83
-16.64
0.15
152.72
6.96
2.23
43.86
-28.93
3.58E-02
143.86
-15.28
0.17
36.42
84
-16.13
0.16
144.48
6.75
2.18
11.94
-28.86
3.61E-02
114.26
-11.71
0.26
20.29
85
-19.10
0.11
166.48
5.98
1.99
-15.86
-29.68
3.28E-02
76.14
-11.91
0.25
11.38
86
-13.97
0.20
134.55
5.16
1.81
-48.54
-31.27
2.73E-02
49.12
-9.97
0.32
-0.26
87
-12.56
0.24
135.11
4.43
1.67
-79.68
-31.35
2.71E-02
10.38
-9.78
0.32
-6.24
88
-11.57
0.26
131.84
4.03
1.59
-115.31
-32.51
2.37E-02
-19.05
-11.31
0.27
-1.38
89
-12.25
0.24
120.86
1.67
1.21
-149.46
-34.59
1.86E-02
-63.31
-8.64
0.37
-2.01
90
-12.49
0.24
126.24
-0.80
0.91
168.79
-35.60
1.66E-02
-93.76
-6.63
0.47
0.98
91
-13.24
0.22
111.67
-3.93
0.64
139.06
-37.67
1.31E-02
-137.97
-4.99
0.56
-3.49
92
-12.60
0.23
116.82
-7.69
0.41
99.48
-42.20
7.76E-03
-120.24
-4.60
0.59
-7.41
93
-15.19
0.17
115.46
-12.24
0.24
70.72
-45.98
5.03E-03
-167.53
-3.23
0.69
-14.77
94
-15.57
0.17
98.36
-15.43
0.17
40.10
-43.49
6.69E-03
148.42
-2.13
0.78
-17.32
95
-15.73
0.16
82.30
-18.17
0.12
15.26
-46.84
4.55E-03
137.70
-2.13
0.78
-29.11
96
-14.37
0.19
97.00
-21.79
0.08
-13.16
-55.96
1.59E-03
153.58
-2.46
0.75
-35.83
97
-12.01
0.25
81.38
-24.88
0.06
-34.33
-48.03
3.97E-03
110.84
-1.60
0.83
-40.19
98
-7.91
0.40
75.00
-27.42
0.04
-66.49
-49.87
3.21E-03
38.33
-0.85
0.91
-52.74
99
-12.46
0.24
65.38
-31.17
0.03
-91.90
-103.00
7.08E-06
92.96
-1.52
0.84
-55.74
100
-11.59
0.26
68.80
-34.78
0.02
-113.10
-71.50
2.66E-04
-26.59
-2.62
0.74
-41.36
Note:
1. Data obtained from an on-wafer condition.
Application and Usage
AMMC-5025 is biased with a single positive drain supply
(Vdd), a negative gate supply (Vg1), and has a positive
control gate supply (Vg2). For best overall performance,
the recommended bias condition for the AMMC-5025 is
Vdd = 5 V and Idd = 100 mA. To achieve this drain current
level, Vg1 is typically –1.8V. Typically, DC current flow for
Vg1 is –10 mA. Open circuit is the default setting for Vg2
when not utilizing gain control. Minor improvements in
performance are possible depending on the application.
The drain bias voltage range is 3 to 6V and the quiescent
drain current biasing range is 80mA to 120mA.
Input and output RF ports are DC coupled; therefore, DC
decoupling capacitors are required if there are DC paths.
RF bond connections should be kept as short as possible
to reduce RF lead inductance which will degrade performance above 20 GHz.
Ground connections are made with plated through-holes
to the backside of the device; therefore, ground wires are
not needed.
8
Using the simplest form of assembly (Figure 11), the
device is capable of delivering flat gain over a 2-80 GHz
range with a minimum of gain slope and ripple. Figure 11
shows a typical assembly application.
However, this device is designed with DC coupled RF I/O
ports, and operation may be extended to lower frequencies (<2 GHz) through the use of off-chip low-frequency
extension circuitry and proper external biasing components. With low frequency bias extension it may be used
in a variety of time-domain applications (through 80
Gb/s).
Refer to the low frequency extension section of Avago
Applications Note 5359 “AMMC-5024 30KHz-40GHz TWA
Operational Guide” for detailed information on use below
2 GHz.
Note:
1. Eutectic attach is not recommended and may jeopardize reliability
of the device.
Vd 1
10:
Aux_Vd
15pF 10: 42:
1pF
480:
280:
RF OUT
50:
50:
Vg2
Vg2
160:
50:
RF_IN
Figure 9. Simplified schematic for AMMC5025
0
100
250
Vg2
1600
430
Vd
Vd_Aux
950
950
700
RF_IN
RF_OUT
250
Vg2
0
0
Vg1
0
Figure 10. Bonding pad location
9
1390
1600
Vg1
VD=+5V
100pF
Vg2: Gain control
4nH Inductor for operation to 2GHz (200mil bond wire)
RF_OUT
RF_IN
100pF
VG=-1.8V
Figure 11. Recommended assemble example
Note: No RF performance degradation is seen due to ESD up to 300V HBM and 70V MM. The user is reminded that this device is ESD sensitive and
needs to be handled with all necessary ESD protocols.
10
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 © 2005-2009 Avago Technologies. All rights reserved.
AV02-2200EN - October 14, 2009
Polybrominated
diphenylether (PBDE)
PBDE