RFMD RF5117PCBA

RF5117
0
3V, 1.8GHz TO 2.8GHz
LINEAR POWER AMPLIFIER
Typical Applications
• IEEE802.11B WLAN Applications
• Commercial and Consumer Systems
• IEEE802.11G WLAN Applications
• Portable Battery-Powered Equipment
• 2.5GHz ISM Band Applications
• Spread-Spectrum and MMDS Systems
Product Description
-A-
The RF5117 is a linear, medium-power, high-efficiency
amplifier IC designed specifically for battery-powered
WLAN applications such as PC cards, mini PCI, and
compact flash applications. 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 2.5GHz WLAN and other
spread-spectrum transmitters. The device is provided in a
3mmx3mm, 16-pin, leadless chip carrier with a backside
ground. The RF5117 is designed to maintain linearity
over a wide range of supply voltage and power output.
0.15 C A
2 PLCS
3.00 SQ.
1.50 TYP
0.80
0.65
12°
MAX
2 PLCS
0.15 C B
-B1.37 TYP
2 PLCS
0.15 C A
-C-
2.75 SQ.
0.10 M C A B
0.60
0.24
TYP
Shaded lead is pin 1.
0.30
0.18
1.65
SQ.
1.35
0.50
9
GaAs HBT
GaAs MESFET
Si Bi-CMOS
SiGe HBT
Si CMOS
InGaP/HBT
GaN HEMT
SiGe Bi-CMOS
SEATING
PLANE
Dimensions in mm.
0.23
0.13
4 PLCS
Si BJT
0.05
0.01
2 PLCS
0.15 C B
0.45
0.00
4 PLCS
Optimum Technology Matching® Applied
0.05 C
1.00
0.85
0.55
0.30
Package Style: QFN, 16-Pin, 3x3
Features
• Single 3.3V Power Supply
NC
NC
VCC
VCC
• +30dBm Saturated Output Power
16
15
14
13
• 26dB Small Signal Gain
• High Linearity
RF IN 1
12 RF OUT
• 1800MHz to 2800MHz Frequency Range
BIAS GND1 2
11 RF OUT
• +17dBm PO, 11G, <3% EVM
PWR SEN 3
10 RF OUT
Bias
7
8
NC
6
9 NC
BIAS GND 2
VREG1
5
VREG2
PWR REF 4
Functional Block Diagram
Rev A7 041007
Ordering Information
RF5117
RF5117 PCBA
3V, 1.8GHz to 2.8GHz Linear Power Amplifier
Fully Assembled Evaluation Board
RF Micro Devices, Inc.
7628 Thorndike Road
Greensboro, NC 27409, USA
Tel (336) 664 1233
Fax (336) 664 0454
http://www.rfmd.com
2-573
RF5117
Absolute Maximum Ratings
Parameter
Supply Voltage
Power Control Voltage (VREG)
DC Supply Current
Input RF Power
Operating Ambient Temperature
Storage Temperature
Moisture sensitivity
Parameter
Rating
Unit
-0.5 to +6.0
-0.5 to 3.5
600
+10
-40 to +85
-40 to +150
JEDEC Level 3
VDC
V
mA
dBm
°C
°C
Specification
Min.
Typ.
Max.
Refer to “Handling of PSOP and PSSOP Products”
on page 16-15 for special handling information.
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).
Unit
Condition
T=25 °C, VCC =3.0V, VREG =2.7V,
Freq=2450MHz, circuit per evaluation board
schematic.
Overall
Frequency Range
Maximum Linear Output Power
1800 to 2800
With 802.11B modulation (11Mbit/s) and
meeting 802.11B spectral mask.
VCC=3.0V
VCC=5.0V
22
27
25
2.5
Linear Efficiency
Error Vector Magnitude (EVM)
Small Signal Gain
Reverse Isolation
Second Harmonic
802.11B Adjacent Channel
Power
Alternate Channel Power
Isolation
Input Impedance
Input VSWR
MHz
24
30
35
dBm
dBm
%
%
26
28.5
-35
-38
-32
dB
dB
dBc
dBc
-56
45
50
2:1
-52
dBc
dB
Ω
2.7
3.0
V
0
0.5
V
PO =17dBm, EVM increases over 11g,
54MBPS signal input
PIN =-7dBm
POUT =21dBm, VCC =3.0V
POUT =21dBm, VCC =3.0V
In “OFF” state, PIN =-5.0dBm
With external matching
With external matching
Power Down
VREG “ON”
VREG “OFF”
2.1
Voltage supplied to control input; device is
“ON”
Voltage supplied to control input; device is
“OFF”
Power Supply
Operating Voltage
Current Consumption
VREG Current (Total)
2-574
3.0 to 5.0
500
200
110
5
10
220
10
15
V
mA
mA
mA
mA
mA
At max output power
POUT =21dBm, VCC =3.0V
Idle current, VCC =3.0V, VREG =2.7V
VCC =3.0V
VCC =5.0V
Rev A7 041007
RF5117
Pin
1
Function
RF IN
Description
Interface Schematic
RF input. Matching network with DC block required, see evaluation
board schematic for details.
VCC
Bond Wire
Inductance
RF IN
BIAS
2
3
BIAS GND1
PWR SEN
Ground for first stage bias circuit. Not connected.
See pin 5.
The PWR SEN and PWR REF pins can be used in conjunction with an
external feedback path to provide an RF power control function for the
RF5117. The power control function is based on sampling the RF drive
to the final stage of the RF5117.
RF OUT
PWR SEN
PWR REF
BIAS
4
5
PWR REF
VREG1
Same as pin 3.
See pin 3.
This pin requires a regulated supply to maintain nominal bias current.
VREG1
BIAS
VREG2
BIAS
GND1
6
7
VREG2
BIAS GND2
8
9
10
NC
NC
RF OUT
11
12
13
RF OUT
RF OUT
VCC
14
15
16
Pkg
Base
VCC
NC
NC
GND
Rev A7 041007
Same as pin 5.
See pin 5.
Ground for second stage bias circuit. For best performance connect to
ground with a 10nH inductor.
Not connected.
See pin 5.
BIAS
GND2
Not connected.
RF output and bias for the output stage. The power supply for the output transistor needs to be supplied to this pin. This can be done
through a quarter-wave length microstrip line that is RF grounded at the
other end, or through an RF inductor that supports the required DC curBIAS
rents.
Same as pin 10.
See pin 10.
Same as pin 10.
See pin 10.
Interstage match and bias for first stage output. Connect interstage
matching capacitor to this pad with a short trace. Connect low-frequency bypass capacitors to this pin with a long trace. See evaluation
board layout for details.
Same as pin 13.
See pin 1.
RF OUT
See pin 1.
Not connected.
Not connected.
Ground connection. The backside of the package should be connected
to the ground plane through a short path, i.e., vias under the device will
be required.
2-575
RF5117
Theory of Operation and Application Information
The RF5117 is a two-stage device with a nominal gain of 26dB in the 2.4GHz to 2.5GHz ISM band. The RF5117 is
designed primarily for IEEE802.11B/11G WLAN applications where the available supply voltage and current are limited.
This amplifier will operate to (and below) the lowest expected voltage made available by a typical PCMCIA slot in a laptop PC, and will maintain required linearity at decreased supply voltages.
The RF5117 requires only a single positive supply of 3.0V nominal (or greater) to operate to full specifications. Power
control is provided through two bias control input pins (VREG1 and VREG2), but in most applications these are tied
together and used as a single control input.
There is some external matching on the input and output of the part, thus allowing the part to be used in other applications outside the 2.4GHz to 2.5GHz ISM band (such as MMDS). Both the input and the output of the device need a
series DC-blocking capacitor. In some cases, a capacitor used as a matching component can also serve as the blocking
cap. The circuit used on the evaluation board is optimized for 3.0V nominal applications.
For best results, the PA circuit layout from the evaluation board should be copied as closely as possible, particularly the
ground layout and ground vias. Other configurations may also work, but the design process is much easier and quicker if
the layout is copied from the RF5117 evaluation board. Gerber files of our designs can be provided upon request.
The RF5117 is not a difficult part to implement, but care in circuit layout and component selection is always advisable
when designing circuits to operate at 2.5GHz. The most critical passive components in the circuit are the input, interstage and output matching components (C1, C5, C7, and C11). In these cases, high-Q capacitors suitable for RF applications are used on our evaluation board (a BOM is available on request). High-Q parts are not required in every design,
but it is very strongly recommended that the original design be implemented with the same or similar parts used on our
evaluation board. Then, less costly components can be substituted in their place, making it easy to test the impact of
cheaper components on performance. General RFMD experience has indicated that the slightly higher cost of better
quality passive components is more than offset by the significant improvements in production yields in large-volume
manufacturing. Using less costly components will typically result in a 1 to 2dB degradation in gain.
The interstage matching capacitor, C11, along with the combined inductance of the internal bond wire, the short length
of circuit board trace, and the parasitic inductance of this capacitor, tunes the peak of the small-signal gain response.
The trace length between C11 and pins 13 and 14 should be kept as short as possible.
In practice, VCC and the supply for the output stage bias will be tied to the same supply. It is important to isolate C11 from
other RF and low-frequency bypass capacitors on this supply line. This can be accomplished using a suitably long transmission line which is RF shorted on the other end. Ideally the length of this line will be a quarter wavelength, but it only
needs to be long enough so that the effects of other supply bypass capacitors on the interstage match are minimized. If
board space is a concern, this isolation can also be accomplished with an RF choke inductor or ferrite bead. Additionally,
a higher-value capacitor than shown on the application schematic can be used if bypass capacitors must be closer. A
Smith Chart can be used to provide initial guidance for value selection and parts placement. Be aware of the self-resonant frequency (SRF) of higher-valued capacitors. The SRF must be above the frequency of operation.
The output matching caps are C5 and C7. These are tuned along with the 50Ω transmission line segments TL1 and TL2,
as shown on the evaluation board schematic. These segments should be duplicated as closely as possible. Due to variations in FR-4 characteristics and PCB manufacturer process variations, some benefit will be obtained from small adjustments to these transmission line lengths when the evaluation board layout is duplicated on another design. Prior to full
rate manufacturing, the board layout of early prototypes should include some additional exposed ground areas around
C5 and C7 to optimize this part of the circuit. In order to reduce component count, the output can also be tuned with a
single capacitor. A Smith Chart can help determine the desired value and transmission line length, which can be similarly
adjusted on the board prior to production. This will result in a slightly lower-bandwidth and more sensitive match, but in
most applications the bandwidth is still sufficient.
2-576
Rev A7 041007
RF5117
Power sensing is implemented with the PWR SEN and PWR REF lines. The outputs of these pins are transistor collectors and need to be pulled up to the supply through a resistor. PWR REF provides an output current proportional to the
output stage bias current, and PWR SEN provides an output current proportional to the total (RF and bias) current of the
output stage. The pull-up resistors convert these currents to voltages, and the voltage difference between these two pins
is proportional to the RF current. See the graph, “VREF -VSENSE versus POUT”, for the response of this signal. This difference signal can be fed to a power control circuit elsewhere in the end product, or it can be processed at the PA with additional circuitry and used to adjust the VREG voltage(s) to implement automatic level control. Contact RFMD Sales or
Applications Engineering for additional data and guidance in using this feature.
The RF5117 has primarily been characterized with a voltage on VREG1 and VREG2 of 2.7VDC. However, the RF5117 will
operate from a wide range of control voltages. If you prefer to use a control voltage that is significantly different than
2.7VDC, contact RFMD Sales or Applications Engineering for additional data and guidance.
Rev A7 041007
2-577
RF5117
Evaluation Board Schematic
2400MHz to 2483MHz
C23
1 µF
VCC
+
C14
1 nF
*3
C11
6.8 pF
Place C11 as
close to chip
as possible
50 Ω µstrip
J1
RF IN
C1
10 pF
L3
1.2 nH
JOH
*2
15
14
1
12
2
11
10
Bias
4
R1
390 Ω
C16
1 nF
L1
12 nH
13
3
R2
390 Ω
C15
1 nF
PWR SENSE
16
C10
1 nF
JOH
Murata
C17
2.7 pF
C2
1 nF
C22
10 µF
C12
1 nF
Part is Backside Grounded.
5
9
6
7
8
C9
10 pF
50 Ω µstrip
C8
10 pF
C7
1.5 pF
JOH
J2
RF OUT
*1
TL1 = 149 mil
(50 Ω)
5117400B
P1
C3
1 nF
PS REF
Notes:
1. C7 - 149 mils from chip.
2. Pin 2 cut from ground.
3. C11 must be placed as close to chip as possible.
*
R3
4.3 kΩ
VREG1
C13
1 nF
VREG2
L2
10 nH
P2
P1-1
1
PS REF
1
GND
P1-2
2
PWR SENSE
2
GND
3
GND
3
VCC
P1-4
4
VREG1
P1-5
5
VREG2
CON5
P2-3
CON3
P3-1
P3
1
VCC
CON1
P4
1
GND
CON1
2-578
Rev A7 041007
RF5117
Evaluation Board Layout
Board Size 1.5” x 2.0”
Board Thickness 0.031”, Board Material FR-4, Multi-Layer
Rev A7 041007
2-579
RF5117
VCC = 3.0, PIN = -5.0 dBm
10.0
180.0
20.0
9.0
20.0
160.0
15.0
8.0
15.0
140.0
10.0
7.0
10.0
120.0
5.0
6.0
5.0
100.0
0.0
5.0
0.0
80.0
-5.0
4.0
-5.0
60.0
-10.0
3.0
-10.0
-15.0
2.0
40.0
IREG (Total) (mA)
25.0
POUT (dBm)
ICC, ICQ (mA)
IREG, POUT versus VREG (Typical)
VCC = 3.0, PIN = -5.0 dBm
25.0
-15.0
Icq
Icq
Icc
20.0
-20.0
1.0
-20.0
Pout
Pout
0.0
-25.0
1.0
1.5
2.0
2.5
0.0
3.0
-25.0
1.0
1.5
2.0
VREG1 , VREG2 (VDC)
* RBW 100 kHz
* VBW 30 kHz
802.11B, 5117 proto
Ref
30
30 dBm
Offset
SWT 35 ms
18.8 dB
1
IFOVL
1 RM *
AVG
20
10
POUT (dBm)
ICQ, ICC, POUT versus VREG (Typical)
200.0
2.5
3.0
VREG1 , VREG2 (VDC)
Marker 1 [T1]
22.01 dBm
2.441839744 GHz
Delta 2 [T1]
-40.55
11.723076923
Delta 3 [T1]
-56.56
-23.900000000
dB
MHz
* RBW 100 kHz
* VBW 30 kHz
SWT 35 ms
802.11B, 5117 proto
Ref
30 dBm
30 Offset
A
dB
MHz
LVL
0
Att
40 dB
18.8 dB
1
IFOVL 20
1 RM *
AVG
10
Marker 1 [T1]
2.441839744 GHz
Delta 2 [T1]
-42.31
11.723076923
Delta 3 [T1]
-58.92
-23.900000000
dB
MHz
dB
MHz
LVL
0
-10
PRN
2
-20
SWP
20 of
-10
PRN
-20
20
SWP
-30
3
-30
-40
3
-40
-50
20 of
20
-50
-60
-60
-70
Center
2
2.442 GHz
5 MHz/
Comment A: 8 MHz int LPF's, Vcc=3.0 Vreg= 2.7, 200 mA
Date:
26.SEP.2001 01:10:29
Span 50 MHz
-70
Center
2.442 G H z
5 MHz/
Span 50 MHz
Comment A: 8 MHz int LPF's, Vcc=Vreg= 2.7, 150 mA
Date:
26.SEP.2001 01:11:53
Spectral Plot: VCC =3.0V, VREG1 =VREG2 =2.7VSpectral Plot: VCC =2.7V, VREG1 =VREG2 =2.7V
POUT =22.05dBm, PIN =-4.1dBm, ICC ~200mAPOUT =19.05dBm, PIN =-6.8dBm, ICC ~150mA
2-580
Rev A7 041007
RF5117
VREF-VSENSE versus POUT
0.5
log10 (V REF-VSENSE )
0.0
-0.5
-1.0
-1.5
-2.0
-2.5
-15.0
-10.0
-5.0
0.0
5.0
10.0
15.0
20.0
25.0
30.0
POUT
Rev A7 041007
2-581
RF5117
EVM versus POUT (11g Tuned PA)
VCC = 3.0V, Gain = 23dB
VCC = 3.3V, Gain = 23dB
140.0
120
6.0
120.0
6.0
100
5.0
100.0
5.0
80.0
4.0
60.0
3.0
Icc(mA)2.4Vreg
Icc(mA)2.5Vreg
Icc(mA)2.6Vreg
Icc(mA)2.7Vreg
EVM%2.4Vreg
EVM%2.5Vreg
EVM%2.6Vreg
EVM%2.7Vreg
ICC (mA)
80
60
4.0
3.0
ICC (mA)
7.0
EVM% (added by PA)
140
40
2.0
40.0
20
1.0
20.0
0.0
0.0
0
14
14.5
25
15
15.5
16
16.5
17
17.5
18
15.5
Icc(mA)2.4Vreg
Icc(mA)2.5Vreg
Icc(mA)2.6Vreg
Icc(mA)2.7Vreg
EVM%2.4Vreg
EVM%2.5Vreg
EVM%2.6Vreg
EVM%2.7Vreg
16.5
17.0
17.5
POUT (dBm)
ICC and Gain for 11b Waveform
in 11g Tuned PA
Gain versus VREG
for 11g Tuned PA
24.5
240
24
230
23.5
220
23
210
22.5
200
22
190
21.5
180
2.0
1.0
0.0
16.0
POUT (dBm)
25
250
7.0
EVM% (added by PA)
EVM versus POUT (11g Tuned PA)
18.0
18.5
19.0
24.5
23.5
Gain (dB)
Total ICC (mA)
Gain (dB)
24
23
22.5
22
21
Gain (3V, Po=22.5dBm)
170
20.5
Gain (3.3V, Po=23dBm)
Icc (3V, Po=22.5dBm)
Icc (3.3V, Po=23dBm)
160
20
150
2.2
2.4
2.6
2.8
3
3.2
3.4
Gain- (VCC=3V)
21.5
Gain- (VCC=3.3V)
21
2.3
2.4
VREG (V)
2.5
2.6
2.7
2.8
VREG (V)
Evaluation Board with 11g Tuning
2-582
Rev A7 041007