RFMD RF2115

RF2115L
2
HIGH POWER UHF AMPLIFIER
Typical Applications
• 400MHz Industrial Radios
• Analog Cellular Systems (AMPS & TACS)
• Driver Stage for Higher Power Applications
• 900MHz Spread-Spectrum Systems
• Portable Battery-Powered Equipment
Product Description
.258
.242
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.242
.150
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GaAs MESFET
SiGe HBT
Si CMOS
RF OUT
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16
NC
NC
1
15
14
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VCC2
P
Si Bi-CMOS
GaAs HBT
VCC3 2
BIAS
CIRCUIT
VCC1 3
S
ee
GND 4
GAIN CONTROL
12 GND
.033
.017
6
7
8
9
G20
G10
NC
Functional Block Diagram
Rev B1 010329
.025
.098
.098
Package Style: QLCC-16
Features
• Single 5V to 6.5V Supply
• Up to 1.0W CW Output Power
• 33dB Small Signal Gain
• 48% Efficiency
• Digitally Controlled Output Power
• Small Package Outline (0.25" x 0.25")
11 RF OUT
10 RF OUT
RF IN
PD 5
13 RF OUT
.022
.018
.050
R
F2
11
R.008
7
.050
Optimum Technology Matching® Applied
Si BJT
.075
.065
1
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The RF2115L is a high power amplifier IC. The device is
manufactured on an advanced Gallium Arsenide Heterojunction Bipolar Transistor (HBT) process, and has been
designed for use as the final RF amplifier in analog cellular phone transmitters or ISM applications operating at
915MHz. The device is packaged in a 16-lead ceramic
quad leadless chip carrier with a backside ground. The
device is self-contained with the exception of the output
matching network and power supply feed line. A two-bit
digital control provides 4 levels of power control, in 10dB
steps.
Ordering Information
RF2115L
RF2115L PCBA
High Power UHF Amplifier
Fully Assembled Evaluation Board
RF Micro Devices, Inc.
7625 Thorndike Road
Greensboro, NC 27409, USA
2
POWER AMPLIFIERS
• Analog Communication Systems
Tel (336) 664 1233
Fax (336) 664 0454
http://www.rfmd.com
2-39
RF2115L
Absolute Maximum Ratings
Parameter
Parameter
Rating
Unit
-0.5 to +8.5
-0.5 to +5.0
-0.5 to +5.5
700
+12
20:1
-40 to +100
-40 to +85
-40 to +150
VDC
V
V
mA
dBm
Caution! ESD sensitive device.
RF Micro Devices believes the furnished information is correct and accurate
at the time of this printing. However, RF Micro Devices reserves the right to
make changes to its products without notice. RF Micro Devices does not
assume responsibility for the use of the described product(s).
°C
°C
°C
Specification
Min.
Typ.
Max.
Unit
Condition
T=25 °C, VCC =5.8V, VPD =5.0V, ZLOAD =9Ω,
PIN =0dBm, Freq=840MHz
40
Idle Current
Power Down “ON”
Power Down “OFF”
dB
dBc
dBc
dBc
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+30.5
+20
+11
+2.5
415
125
56
38
55
5.0
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+30
+17
+7
-4
350
75
35
21
30
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Power Supply Current
dBm
dBm
dBm
%
33
-23
-36
-35
<2:1
50
Power Control
Output Power
MHz
dBm
+30
+29.5
+28.5
48
P
Total CW Efficiency at Maximum
Output
Small-signal Gain
Second Harmonic
Third Harmonic
Fourth Harmonic
Input VSWR
Input Impedance
430 to 930
+30.5
0
Note that increasing VCC does not result in
higher output power; power may actually
decrease.
VCC =5.8V, ZLOAD=12Ω
VCC =5.0V, ZLOAD=9Ω
VCC =5.0V, ZLOAD=12Ω
R
F2
11
Frequency Range
Maximum CW Output Power
7
Overall
Without external second harmonic trap
Ω
0.2
dBm
dBm
dBm
dBm
mA
mA
mA
mA
mA
V
V
G20
G10
1
1
1
0
0
1
0
0
1
1
1
0
0
1
0
0
1
1
Voltage supplied to the input; Part is “ON”
Voltage supplied to the input; Part is “OFF”
0.2
10
V
V
µA
Voltage supplied to the input; Part is “ON”
Voltage supplied to the input; Part is “OFF”
VPD < 0.1 VDC
+36
+23
+13
+6
600
175
90
50
80
Power Down Control
Power Down “ON”
Power Down “OFF”
Current Drain
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POWER AMPLIFIERS
2
Supply Voltage (VCC)
Power Down Voltage (VPD)
Control Voltage (G10, G20)
DC Supply Current
Input RF Power
Output Load
Operating Case Temperature
Operating Ambient Temperature
Storage Temperature
2-40
5.0
0
1
Rev B1 010329
RF2115L
Function
VCC2
VCC3
3
VCC1
4
GND
5
PD
6
RF IN
7
G20
Interface Schematic
Positive supply for the second stage (driver) amplifier. This is an
unmatched transistor collector output. This pin should see an inductive
path to AC ground (VCC with a UHF bypassing capacitor). This inductance can be achieved with a short, thin microstrip line or with a low
value chip inductor (approximately 2.7nH). At lower frequencies, the
inductance value should be larger (longer microstrip line) and VCC
should be bypassed with a larger bypass capacitor (see the application
schematic for 430MHz operation). This inductance forms a matching
network with the internal series capacitor between the second and third
stages, setting the amplifier’s frequency of maximum gain. An additional 1µF bypass capacitor in parallel with the UHF bypass capacitor is
also recommended, but placement of this component is not as critical.
In most applications, pins 1, 2, and 3 can share a single 1µF bypass
capacitor.
Positive supply for the active bias circuits. This pin can be externally
combined with pin 3 (VCC1) and the pair bypassed with a single UHF
capacitor, placed as close as possible to the package. Additional
bypassing of 1µF is also recommended, but proximity to the package is
not as critical. In most applications, pins 1, 2, and 3 can share a single
1µF bypass capacitor.
Positive supply for the first stage (input) amplifier. This pin can be externally combined with pin 2 (VCC3) and the pair bypassed with a single
UHF capacitor, placed as close as possible to the package. Additional
bypassing of 1µF is also recommended, but proximity to the package is
not as critical. In most applications, pins 1, 2, and 3 can share a single
1µF bypass capacitor. This pin can also be used for coarse analog gain
control, even though it is not optimized for this function.
Ground connection. Keep traces physically short and connect immediately to ground plane for best performance. In addition, for specified
performance, the package’s backside metal should be soldered to
ground plane.
Power down control voltage. When this pin is at 0V, the device will be in
power down mode, dissipating minimum DC power. When this pin is at
5V the device will be in full power mode delivering maximum available
gain and output power capability. This pin may also be used to perform
some degree of gain control or power control when set to voltages
between 0V and 5V. It is not optimized for this function so the transfer
function is not linear over a wide range as with other devices specifically designed for analog gain control; however, it may be usable for
coarse adjustment or in some closed loop AGC systems. This pin
should not, in any circumstance, be higher in voltage than VCC, nor
should it ever be higher than 6.5V. This pin should also have an external UHF bypassing capacitor.
Amplifier RF input. This is a 50Ω RF input port to the amplifier. It does
not contain internal DC blocking and therefore should be externally DC
blocked before connecting to any device which has DC present or
which contains a DC path to ground. A series UHF capacitor is recommended for the DC blocking.
RF output power gain control MSB (see specification table for logic).
The control voltage at this pin should never exceed VCC. This pin
should also have an external UHF bypassing capacitor.
RF output power gain control LSB (see specification table for logic).
The control voltage at this pin should never exceed VCC. This pin
should also have an external UHF bypassing capacitor.
Not internally connected.
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2
Description
POWER AMPLIFIERS
Pin
1
8
G10
9
NC
Rev B1 010329
2-41
RF2115L
11
12
13
14
15
16
Pkg
Base
RF OUT
GND
RF OUT
RF OUT
NC
NC
GND
Interface Schematic
Amplifier RF output. This is an unmatched collector output of the final
amplifier transistor. It is internally connected to pins 10, 11, 13, and 14
to provide low series inductance and flexibility in output matching. Bias
for the final power amplifier output transistor must also be provided
through two of these four pins. Typically, pins 10 and 11 are connected
to a network that creates a second harmonic trap. For 830MHz operation, this network is simply a single 2.4pF capacitor from both pins to
ground. This capacitor series resonates with internal bond wires at two
times the operating frequency, effectively shorting out the second harmonic. Shorting out this harmonic serves to increase the amplifier’s
maximum output power and efficiency, as well as to lower the level of
the second harmonic output. Typically, pins 13 and 14 are externally
connected very close to the package and used as the RF output with a
matching network that presents the optimum load impedance to the PA
for maximum power and efficiency, as well as providing DC blocking at
the output. An additional network of a bias inductor and parallel resistor
provides DC bias and helps to protect the output from high voltage
swings due to severe load mismatches. Shunt protection diodes are
included to clip peak voltage excursions above approximately 15V to
prevent voltage breakdown in worst case conditions.
Same as pin 10.
Same as pin 4.
Same as pin 10.
Same as pin 10.
Not internally connected.
Not internally connected.
This contact is the main ground contact for the entire device. Care
should be taken to ensure that this contact is well soldered in order to
prevent performance from being degraded from that indicated in the
specifications.
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POWER AMPLIFIERS
2
Description
7
Function
RF OUT
R
F2
11
Pin
10
2-42
Rev B1 010329
RF2115L
Application Schematic
430MHz
16 nH
33 pF
4.7 nH
16
15
14
16 pF
2
15 pF
2
13
BIAS
CIRCUIT
3
12
4
11
POWER AMPLIFIERS
1
RF OUT
100 pF
PD
0/5 VDC
GAIN CONTROL
5
15 nH
10
13 pF
100 pF
6
7
8
100 pF
9
RF IN
100 pF
Ground Back of
Package
1
µF
BIT 1
0V / V CC
BIT 2
0V / V CC
7
22 pF
R
F2
11
22 pF
VCC
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Application Schematic
840MHz
VCC
1 µF
47 nH
100 pF
P
180 Ω
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0.01" x 0.2"
(PCB material: FR-4,
Thickness: 0.031")
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100 pF
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PD
0/5 VDC
1.8 nH
1
16
15
RF OUT
14
4.7 pF
2
13
BIAS
CIRCUIT
3
12
4
11
100 pF
GAIN CONTROL
5
2.4 pF
10
100 pF
6
7
8
9
RF IN
Ground Back of
Package
100 pF
100 pF
BIT 1
0V / V CC
Rev B1 010329
6.8 pF
100 pF
BIT 2
0V / V CC
2-43
RF2115L
Evaluation Board Schematic
840MHz Operation
(Download Bill of Materials from www.rfmd.com.)
P1
P1-1
POWER AMPLIFIERS
C14
100 nF
P1-3
P2
1
VCC
2
GND
3
PD
P2-1
P2-3
1
B2
2
GND
3
B1
R3
180 Ω
2115400 Rev -
P1-1
C8
100 nF
C6
100 pF
0.01" x 0.2"
(PCB mat'l: FR-4,
Thickness: 0.031")
L2
1.8 nH
1
2
C5
100 pF
C4
100 pF
16
BIAS
CIRCUIT
3
SMA
J1 50 Ω µ strip
RF
IN
C12
4.7 pF
14
50 Ω µ strip
SMA
J2
RF
OUT
13
11
GAIN CONTROL
5
C3
330 pF
15
C2
6.8 pF
12
4
P1-3
L1
47 nH
C11
100 nF
C7
330 pF
7
C9
1nF
R
F2
11
C10
1 µF
C13
2.4 pF
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2
6
7
R1
1 kΩ
9
R2
1 kΩ
P2-3 P2-1
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C1
100 pF
8
2-44
Rev B1 010329
RF2115L
Evaluation Board Layout
2” x 3”
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7
POWER AMPLIFIERS
2
Rev B1 010329
2-45
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R
F2
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7
POWER AMPLIFIERS
RF2115L
2
2-46
Rev B1 010329