AVAGO AMMP-6333-TR1G 18 â 33 ghz, 0.2 w driver amplifier in smt package Datasheet

AMMP-6333
18 – 33 GHz, 0.2 W Driver Amplifier in SMT Package
Data Sheet
Description
Features
The AMMP-6333 is a broadband 0.2 W driver amplifier
designed for use in transmitters operating in various
frequency bands from 18 GHz to 33 GHz. This small, easy to
use device provides over 23 dBm of output power (P-1dB)
and more than 20 dB of gain at 25 GHz. It was optimized
for linear operation with an output power at the third
order intercept point (OIP3) of 30dBm. The AMMP-6333
features a temperature compensated RF power detection
circuit that enables power detection sensitivity of 0.3
V/W at 25GHz. It is fabricated using Avago Technologies
unique 0.25μm E-mode PHEMT technology which eliminates the need for negative gate biasing voltage.
• Frequency range: 18 to 33 GHz
Package Diagram
• Small signal gain: 20 dB
• P-1dB : 23dBm
• Return Loss (In/Out): -10 dB
Applications
• Microwave Radio systems
• Satellite VSAT, Up/Down Link
• LMDS & Pt-Pt mmW Long Haul
• Broadband Wireless Access (including 802.16 and
802.20 WiMax)
• WLL and MMDS loops
Vg
Vd
DET_O
1
2
3
Functional Block Diagram
1
RF IN
8
4
2
3
RF OUT
8
7
6
5
NC
Vd
DET_R
4
7
6
5
Pin
Function
1
2
3
4
5
6
7
8
Vg
Vd
DET_O
RF_out
DET_R
Vd
NC
RF_in
Attention: Observe precautions for
handling electrostatic sensitive devices.
ESD Machine Model (Class A) = 90 V
ESD Human Body Model (Class 1A) = 300 V
Refer to Avago Application Note A004R:
Electrostatic Discharge, Damage and Control.
Note: MSL Rating = Level 2A
Electrical Specifications
1. Small/Large -signal data measured in a fully de-embedded test fixture form TA = 25°C.
2. Pre-assembly into package performance verified 100% on-wafer per AMMC-6220 published specifications.
3. This final package part performance is verified by a functional test correlated to actual performance at one or more
frequencies.
4. Specifications are derived from measurements in a 50 Ω test environment. Aspects of the amplifier performance may
be improved over a more narrow bandwidth by application of additional conjugate, linearity, or low noise (Гopt)
matching.
5. All tested parameters guaranteed with measurement accuracy +/- 2dB for P1dB of 17,25 and 32GHz +/- 0.5 for Gain
of 17GHz, +/- 1 dB for Gain of 25 and 32GHz
Table 1. RF Electrical Characteristics
TA=25°C, Vd=3.0V, Id(Q)=230mA, Zin=Zo=50 Ω
17-20GHz
Parameter
Min
Small Signal Gain, Gain
14
16
19
Output Power at 1dBGain Compression,
P1dB
18
20.5
22
Output Power at 3dBGain Compression,
P3dB
Typ
20-30GHz
Max
Min
Typ
30-33GHz
Max
Min
Typ
Max
Unit
22
18
20.5
24.5
21
24
dBm
Comment
dB
21.5
24.5
23.5
dBm
Output Third Order Intercept Point,
OIP3
30
30
30
dBm
Reverse Isolation, Iso
45
45
45
dB
Input Return Loss, Rlin
10
10
8
dB
Output Return Loss, RLout
10
14
10
dB
Table 2. Recommended Operating Range
1. Ambient operational temperature TA = 25°C unless otherwise noted.
2. Channel-to-backside Thermal Resistance (Tchannel (Tc) = 34°C) as measured using infrared microscopy.
Thermal Resistance at backside temperature (Tb) = 25°C calculated from measured data.
Description
Min.
Typical
Max.
Unit
Comments
Drain Supply Current, Id
230
mA
Vd=5 V, Vg set for typical IdQ –
quiescent current
Gate Supply Operating Voltage, Vg
2
V
IdQ = 230 mA
Gate Supply Current, Ig
7
mA
2
Table 3. Thermal Properties
Parameter
Test Conditions
Value
Maximum Power Dissipation
Tbaseplate = 85°C
PD = 2.5W
Tchannel = 150°C
Thermal Resistance, qjc
Vd = 5V
Id = 230mA
PD = 1.15W
Tbaseplate = 85°C
qjc = 27 °C/W
Tchannel = 116°C
Thermal Resistance, qjc
Under RF Drive
Vd = 5V
Id = 400mA
Pout = 24dBm
PD = 2W
Tbaseplate = 85°C
qjc = 27 °C/W
Tchannel = 139°C
Absolute Minimum and Maximum Ratings
Table 4. Minimum and Maximum Ratings
Description
Max.
Unit
Drain to Gate Voltage, Vd-Vg
14
V
Positive Supply Voltage, Vd
5.5
V
Gate Supply Voltage, Vg
0 to 2.5
V
Power Dissipation, PD
2.5
W
CW Input Power, Pin
20
dBm
Channel Temperature, Tch
+150
°C
+155
°C
320
°C
Storage Temperature, Tstg
Maximum Assembly Temperature, Tmax
Min.
-65
Notes:
1. Operation in excess of any one of these conditions may result in permanent damage to this device.
3
Comments
30 second maximum
Typical Performance
(TA = 25°C, Vd =5 V, IdQ = 230 mA, Zin = Zout = 50 Ω)
(Data obtained from a test fixture with 2.4 mm connectors. Effects of the test fixture – losses and mismatch – have not
been removed from the data)
40
0
0
S21[dB]
S12[dB]
30
-40
15
10
S12 [dB]
S21[dB]
25
20
S11[dB]
S22[dB]
-5
-20
Return Loss [dB]
35
-10
-60
-15
-80
-20
5
0
10
15
20
25
30
Frequency [GHz]
35
40
10
20
25
30
Frequency [GHz]
30
20
P-1
PAE
40
SCL=20[dBm]
SCL=10dBm]
SCL=5[dBm]
10
0
IMD3 Level [dBc]
25
35
Figure 2. Return Loss vs Frequency
Figure 1. Gain and Reverse Isolation vs Frequency
P-1 [dBm], PAE [%]
15
20
15
-10
-20
-30
-40
-50
-60
10
18
20
22
24
26
Frequency [GHz]
28
30
32
-70
34
Figure 3. P-1dB and PAE vs Frequency
21
23 25 27
Frequency [GHz]
29
31
33
35
Pout(dBm)
PAE[%]
Id(total)
25
Po[dBm], and, PAE[%]
Noise Figure [dB]
19
400
30
8
6
4
2
20
300
15
10
5
16
18
20
22
24
26
Frequency [GHz]
Figure 5. Typical Noise Figure vs Frequency
4
17
Figure 4. Typical IMD3 vs Frequency (SCL = Single Carrier level)
10
0
15
Ids [mA]
16
28
30
32
34
0
-25
-20
-15
-10
-5
Pin [dBm]
0
5
200
Figure 6. Output Power, PAE, and Drain Current vs Input Power at 30GHz
Typical Performance (continued)
(TA = 25°C, Zin = Zout = 50 Ω)
(Data obtained from a test fixture with 2.4 mm connectors. Effects of the test fixture – losses and mismatch – have not
been removed from the data)
24
27
22
25
20
Gain [dB]
P-1[dBm
23
21
19
15
15
17
19
21
23 25 27
Frequency[GHz]
29
31
33
8
35
27
27
25
25
15
17
19
21
23 25 27
Frequency[GHz]
29
31
33
35
33
35
23
P1 [dBm]
21
19
17
Gain[Vds=3V]
Gain[Vds=4V]
Gain[Vds=5V]
15
13
Gain[@180mA]
Gain[@230mA]
Gain[@280mA]
Figure 8. Small signal gain vs Frequency and IdQ, (Vds=5V)
23
Gain[dB]
14
10
Figure 7. P-1dB vs Frequency and Vds, (IdQ=230mA)
15
17
19
21
23 25 27
Frequency[GHz]
29
21
19
P-1[@180mA]
P-1[@230mA]
P-1[@280mA]
17
31
Figure 9. Small signal gain vs Frequency and Vds, (IdQ=230mA)
5
16
12
P-1[Vds=3V]
P-1[Vds=4V]
P-1[Vds=5V]
17
18
33
35
15
15
17
19
21
23 25 27
Frequency[GHz]
Figure 10. P-1dB vs Frequency and IdQ, (Vds=5V)
29
31
Typical Performance (continued)
(Vd =5 V, IdQ = 230 mA, Zin = Zout = 50 Ω)
(Data obtained from a test fixture with 2.4 mm connectors. Effects of the test fixture – losses and mismatch – have not
been removed from the data)
0
0
S11_25
S11_-40
S11_85
-5
S22[dB]
S11[dB]
-5
-10
-15
15
17
19
21
23 25 27
Frequency [GHz]
29
31
33
30
27
25
25
20
23
15
S21_25
S21_-40
S21_85
10
15
17
19
21
23 25 27
Frequency [GHz]
Figure 13. |S21| vs Frequency and Temperature
15
17
19
21
23 25 27 29
Frequency [GHz]
31
33
35
31
33
35
Figure 12. |S22| vs Frequency and Temperature
P-1 [dBm]
S21[dB]
-20
35
Figure 11. |S11| vs Frequency and Temperature
6
-10
-15
-20
5
S22_25
S22_-40
S22_85
21
P-1_85deg
P-1_25deg
P-1_-40deg
19
29
31
33
35
17
15
17
19
21
23 25 27 29
Frequency [GHz]
Figure 14. P-1dB vs Frequency and Temperature
Biasing Considerations
The AMMP-6333 is a balanced amplifier consisting of two
four stage single-ended amplifiers, two Lange couplers, a
power monitoring detector, a reference detector for temperature compensation, and a current mirror for the gate
biasing (Figure 15).
The recommended quiescent DC bias conditions for
optimum gain, output power, efficiency, and reliability
are: Vd = 5 V with Vg set for IdQ = 230 mA. The drain bias
voltage range is from 3 to 5 V. Drain current range is from
200 mA to 350 mA. The AMMC-6333 can be biased with a
dual or single positive DC source (Figure 16).
The output power detection network provides a way to
monitor output power. The differential voltage between
the DET_R and DET_O outputs can be correlated with the
RF power emerging from the RF output port. This voltage
is given by:
V = (VDET_R – VDET_O) – VOFS
Where:
VDET_R is the voltage at the DET_R port
VDET_O is a voltage at the DET_O port
VOFS is the offset voltage at zero input power
The offset voltage (VOFS) can be at each power level by
turning off the input power and measuring V. The error
due to temperature drift should be less than 0.01dB/50°C.
When VOFS is determined at a single reference temperature the drift error should be less than 0.25dB. Finally,
VOFS be characterized over a range of temperatures and
stored in a lookup table, or it can be measured at two
temperatures and a linear fit used to calculate VOFS at any
temperature.
The RF ports are AC coupled at the RF input to the first
stage and the RF output of the final stage. No ground
wires are needed since ground connections are made
with plated through-holes to the backside of the device.
Vg
Vd
DET_O
RFout
RFin
Four stage wideband amplifier
Vd
DET_R
Figure 15. AMMC-6333 schematic
7
1. Dual positive DC power supply
2V
100 pF
1µF
2. Single positive DC power supply
100 pF
100 p
1µF
400
DET_O
1
RF Input
2
1
3
8
RF Output
4
7
6
RF Input
2
3
4
7
5
DET_O
8
6
RF Output
5
DET_R
DET_R
100 pF
1 F
100 pF
5V
5V
Note:
1. Vdd may be applied to
either Pin 2 or Pin 6.
Figure 16. AMMP-6333 assembly examples, Vd pins must be biased from both sides
1
0.30
0.1
0.20
0.15
0.01
0.10
Det_R - Det_O [V]
Det_R - Det_O [V]
0.25
0.05
0
0.001
5
10
15
Pout[dBm]
20
25
Figure 17. AMMP-6333 Typical Detector Voltage and Output Power, Freq=30GHz
8
Typical Scattering Parameters
Please refer to <http://www.avagotech.com> for typical scattering parameters data.
Package Dimension, PCB Layout and Tape and Reel information
Please refer to Avago Technologies Application Note 5520, AMxP-xxxx production Assembly Process (Land Pattern A).
Ordering Information
Part Number
Devices Per
Container
Container
AMMP-6333-BLKG
10
Antistatic bag
AMMP-6333-TR1G
100
7” Reel
AMMP-6333-TR2G
500
7” Reel
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 © 2005-2013 Avago Technologies. All rights reserved.
AV02-1447EN - July 9, 2013
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