AGILENT AT

Up to 6 GHz Medium Power
Silicon Bipolar Transistor
Technical Data
AT-42010
Features
• High Output Power:
12.0 dBm Typical P1 dB at 2.0␣ GHz
20.5 dBm Typical P1 dB at 4.0␣ GHz
• High Gain at
1␣ dB␣ Compression:
14.0 dB Typical G1 dB at 2.0␣ GHz
9.5 dB Typical G1 dB at 4.0␣ GHz
• Low Noise Figure:
1.9 dB Typical NFO at 2.0␣ GHz
• High Gain-Bandwidth
Product: 8.0 GHz Typical fT
• Hermetic Gold-ceramic
Microstrip Package
Description
Hewlett-Packard’s AT-42010 is a
general purpose NPN bipolar
transistor that offers excellent
high frequency performance. The
AT-42010 is housed in a hermetic,
high reliability 100 mil ceramic
package. The 4 micron emitter-toemitter pitch enables this transistor to be used in many different
5965-8910E
functions. The 20 emitter finger
interdigitated geometry yields a
medium sized transistor with
impedances that are easy to match
for low noise and medium power
applications. This device is
designed for use in low noise,
wideband amplifier, mixer and
oscillator applications in the VHF,
UHF, and microwave frequencies.
An optimum noise match near
50␣ Ω up to 1 GHz , makes this
device easy to use as a low noise
amplifier.
The AT-42010 bipolar transistor is
fabricated using Hewlett-Packard’s
10 GHz fT Self-Aligned-Transistor
(SAT) process. The die is nitride
passivated for surface protection.
Excellent device uniformity,
performance and reliability are
produced by the use of ionimplantation, self-alignment
techniques, and gold metalization
in the fabrication of this device.
4-154
100 mil Package
AT-42010 Absolute Maximum Ratings [1]
Symbol
VEBO
VCBO
VCEO
IC
PT
Tj
TSTG
Parameter
Emitter-Base Voltage
Collector-Base Voltage
Collector-Emitter Voltage
Collector Current
Power Dissipation [2,3]
Junction Temperature
Storage Temperature
Absolute
Maximum
1.5
20
12
80
600
200
-65 to 200
Units
V
V
V
mA
mW
°C
°C
Thermal Resistance [2,4]:
θjc = 150°C/W
Notes:
1. Permanent damage may occur if
any of these limits are exceeded.
2. TCASE = 25°C.
3. Derate at 6.7 mW/°C for
TC > 110°C.
4. The small spot size of this technique results in a higher, though
more accurate determination of θjc
than do alternate methods. See
MEASUREMENTS section
“Thermal Resistance” for more
information.
Electrical Specifications, TA = 25°C
Symbol
Parameters and Test Conditions[1]
Units
Min.
Typ. Max.
10.5
11.5
5.5
|S21E|2
Insertion Power Gain; VCE = 8 V, IC = 35 mA
f = 2.0 GHz
f = 4.0 GHz
dB
P1 dB
f = 2.0 GHz
f= 4.0 GHz
f = 2.0 GHz
f = 4.0 GHz
dBm
G1 dB
Power Output @ 1 dB Gain Compression
VCE = 8 V, IC = 35 mA
1 dB Compressed Gain; VCE = 8 V, IC = 35 mA
NFO
Optimum Noise Figure: VCE = 8 V, IC = 10 mA
dB
GA
Gain @ NFO; VCE = 8 V, IC = 10 mA
f = 2.0 GHz
f = 4.0 GHz
f = 2.0 GHz
f = 4.0 GHz
fT
Gain Bandwidth Product: VCE = 8 V, IC = 35 mA
hFE
ICBO
IEBO
CCB
Forward Current Transfer Ratio; VCE = 8 V, IC = 35 mA
Collector Cutoff Current; VCB = 8 V
Emitter Cutoff Current; VEB = 1 V
Collector Base Capacitance[1]: VCB = 8 V, f = 1 MHz
Notes:
1. For this test, the emitter is grounded.
4-155
21.0
20.5
14.0
9.5
dB
1.9
3.0
13.5
10.0
dB
GHz
—
µA
µA
pF
8.0
30
150
0.28
270
0.2
2.0
AT-42010 Typical Performance, TA = 25°C
24
2.0 GHz
12
2.0 GHz
20
4.0 GHz
P1dB
16
6V
16
4V
P1dB
12
12
0
0
10
20
30
40
G1dB
8
4
50
16
G1 dB (dB)
4.0 GHz
4
4.0 GHz
0
10
20
IC (mA)
30
40
24
35
21
18
GAIN (dB)
25
20
MAG
15
|S21E|2
10
15
12
4
9
3
6
5
2
NFO
3
0
0.1
0.3 0.5
1.0
3.0
6.0
FREQUENCY (GHz)
Figure 4. Insertion Power Gain,
Maximum Available Gain and
Maximum Stable Gain vs. Frequency.
VCE = 8 V, IC = 35 mA.
0
0.5
1
1.0
2.0
0
3.0 4.0 5.0
FREQUENCY (GHz)
Figure 5. Noise Figure and Associated
Gain vs. Frequency.
VCE = 8 V, IC = 10mA.
4-156
NFO (dB)
MSG
0
10
20
30
40
50
Figure 3. Output Power and 1 dB
Compressed Gain vs. Collector
Current and Voltage. f = 2.0 GHz.
GA
30
G1dB
12
IC (mA)
Figure 2. Output Power and 1 dB
Compressed Gain vs. Collector
Current and Frequency. VCE = 8 V.
40
10 V
6V
4V
14
10
50
IC (mA)
Figure 1. Insertion Power Gain vs.
Collector Current and Frequency.
VCE = 8 V.
GAIN (dB)
10 V
20
2.0 GHz
8
G1 dB (dB)
|S21E|2 GAIN (dB)
16
24
P1 dB (dBm)
1.0 GHz
P1 dB (dBm)
20
AT-42010 Typical Scattering Parameters, Common Emitter,
ZO = 50 Ω, TA = 25°C, VCE = 8 V, IC␣
Freq.
S11
GHz
Mag.
Ang.
0.1
.74
-47
0.5
.65
-136
1.0
.63
-168
1.5
.63
174
2.0
.63
161
2.5
.64
154
3.0
.65
145
3.5
.66
136
4.0
.66
126
4.5
.66
115
5.0
.66
103
5.5
.68
90
6.0
.72
81
=␣ 10 mA
dB
28.5
21.4
15.9
12.6
10.1
8.4
6.9
5.8
4.7
3.8
3.0
2.1
1.3
S21
Mag.
26.65
11.71
6.24
4.26
3.23
2.64
2.22
1.94
1.72
1.55
1.41
1.28
1.16
Ang.
153
103
82
69
57
51
41
31
21
11
1
-9
-19
dB
-36.4
-29.4
-27.2
-26.0
-24.6
-23.0
-22.0
-21.0
-19.7
-18.0
-17.3
-16.1
-15.4
S12
Mag.
.015
.034
.044
.050
.059
.070
.080
.090
.104
.126
.136
.156
.170
Ang.
72
38
36
42
43
52
54
51
50
45
41
36
31
Mag.
.91
.51
.40
.38
.38
.38
.37
.38
.39
.40
.40
.40
.37
S22
dB
-39.2
-33.2
-28.8
-26.2
-23.8
-21.8
-21.0
-19.7
-18.4
-17.2
-16.6
-15.6
-14.9
S12
Mag.
.011
.022
.036
.049
.065
.081
.090
.103
.120
.138
.148
.166
.180
Ang.
54
52
59
61
57
62
63
59
54
49
45
39
32
Mag.
.76
.34
.30
.29
.29
.29
.30
.30
.31
.33
.34
.33
.30
Ang.
-18
-39
-42
-45
-49
-51
-56
-65
-74
-82
-89
-98
-110
AT-42010 Typical Scattering Parameters,
Common Emitter, ZO = 50 Ω, TA = 25°C, VCE = 8 V, IC␣ =␣ 35 mA
Freq.
S11
S21
GHz
Mag.
Ang.
dB
Mag.
Ang.
0.1
.54
-90
33.3
45.97
138
0.5
.62
-163
22.8
13.83
94
1.0
.62
177
17.0
7.10
78
1.5
.62
166
13.6
4.82
67
2.0
.62
155
11.3
3.65
56
2.5
.63
150
9.5
2.99
51
3.0
.64
142
8.0
2.52
42
3.5
.65
133
6.8
2.19
32
4.0
.65
124
5.7
1.93
22
4.5
.65
113
4.7
1.72
13
5.0
.66
102
3.9
1.56
3
5.5
.69
91
3.0
1.41
-6
6.0
.73
83
2.1
1.27
-16
A model for this device is available in the DEVICE MODELS section.
AT-42010 Noise Parameters: VCE = 8 V, IC = 10 mA
Freq.
GHz
NFO
dB
0.1
0.5
1.0
2.0
4.0
1.0
1.1
1.5
1.9
3.0
Γopt
Mag
.04
.05
.10
.23
.45
Ang
15
76
132
-177
-125
4-157
RN/50
0.13
0.12
0.12
0.11
0.26
S22
Ang.
-29
-40
-40
-42
-47
-50
-57
-67
-76
-85
-92
-100
-110
100 mil Package Dimensions
.040
1.02
4
EMITTER
.020
.508
BASE
COLLECTOR
3
1
2
.004 ± .002
.10 ± .05
EMITTER
.100
2.54
.495 ± .030
12.57 ± .76
Notes:
(unless otherwise specified)
1. Dimensions are in
mm
2. Tolerances
in .xxx = ± 0.005
mm .xx = ± 0.13
.030
.76
4-158