ETC PF0147

PF0147
MOS FET Power Amplifier Module
for GSM Handy Phone
ADE-208-322D (Z)
5th. Edition
June, 1996
Application
For GSM class4 890 to 915MHz.
Features
•
•
•
•
2stage amplifier
Small package: 0.6cc
High efficiency: 40% Typ
High speed switching: 0.9µsec Typ
Pin Arrangement
• RF-H1
5
5
1
2
3
1: Pin
2: VAPC
3: VDD
4: Pout
5: GND
4
Absolute Maximum Ratings (Tc = 25°C)
Item
Symbol
Rating
Unit
Supply voltage
VDD
10
V
Supply current
IDD
3
A
VAPC voltage
VAPC
6
V
Input power
Pin
20
mW
Operating case temperature
Tc (op)
–30 to +100
°C
Storage temperature
Tstg
–30 to +100
°C
Output power
Pout
7
W
PF0147
Internal Diagram
G
G
G
G: GND
PIN1
Pin
G
PIN2
VAPC
PIN3
VDD
PIN4
Pout
Electrical Characteristics (Tc = 25°C)
Item
Symbol
Min
Typ
Max
Unit
Frequency range
f
890
—
915
MHz
Control voltage
range
VAPC
0.5
—
3.5
V
—
—
100
µA
VDD = 10V, VAPC = 0V
Drain cutoff current IDS
Test Condition
Total efficiency
ηT
35
40
—
%
Pin = 10mW, VDD = 4.8V,
2nd harmonic
distortion
2nd H.D.
—
–50
–40
dBc
Pout = 3.2W (at APC
controlled),
3rd harmonic
distortion
3rd H.D.
—
–50
–40
dBc
RL = Rg = 50Ω, Tc = 25°C
Input VSWR
VSWR (in) —
2
3
—
Output power (1)
Pout (1)
3.2
3.8
—
W
Pin = 10mW, VDD = 4.8V,
VAPC = 3.5V, RL = Rg = 50Ω,
Tc = 25°C
Output power (2)
Pout (2)
1.8
2.4
—
W
Pin = 10mW, VDD = 4.3V,
VAPC = 3.5V, RL = Rg = 50Ω,
Tc = 80°C
Isolation
—
—
—
–20
dBm
Pin = 10mW, VDD = 4.8V,
VAPC = 0.5V, RL = Rg = 50Ω,
Tc = 25°C
Switching time
tr, tf
—
0.9
2
µs
Pin = 10mW, VDD = 4.8V,
Pout = 3.2W, RL = Rg = 50Ω,
Tc = 25°C
Stability
—
No parasitic oscillation
—
Pin = 10mW, VDD = 6.0V,
Pout ≤ 3.2W (at APC
controlled),
Rg = 50Ω, t = 20sec., Tc =
25°C,
Output VSWR = 10 : 1 All
phases
PF0147
Test System Diagram
S.G
VAPC VDD
Power
Meter
Spectrum
Analyzer
3dB
ATT
L.P.F
TEST
FIXTURE
Power Meter
RF SW.
Directional
Coupler
Directional
Coupler
Phase
Shifter
Short
Switching Time Test Diagram
VDD = 4.8V
S.G
Z=50Ω
Pin
Power
Meter
D.U.T
Pout
P.G
2p
2p
VAPC
f = 217Hz
1SS106
100p
Oscillo
Scope
1SS106
2.2kΩ
Vout
Duty=1/8
50%
50%
VAPC
95%
5%
Pout
tr
tf
PF0147
Test Fixture
Test Circuit
Pin
VAPC
Z1
VDD
FB1
Pin
C2
+
FB2
VAPC
VDD
Pout
C1
Z2
Pout
C1 = 0.01µF Ceramic chip
C2 = 220µF Aluminum electrolyte
FB = Ferrite bead BLO1RN1-A62-001 (MURATA) or equivalent
Z1 = Z2 = 50Ω Micro strip line
Printed Circuit Board Layout
41.87
16.26
41.87
5
30
2.88
5
5 6.5
2 2
5
5
5
7
80
5
7
100
Grass Epoxy Double sided P.C.B
(t=1.6mm, εr=4.8)
Unit: mm
: Through hole
(φ=1mm)
PF0147
Note for Use
• At evaluation of a sample, take the drop of VDD voltage and power loss on test P.C.B. into account.
• Apply control voltage range as VAPC = 0.5 to 3.5V, and GSM burst mode must be applied to all
operation. For instance, pulse width = 0.577msec., duty = 12.5% and VAPC ≤ 0.5V, for all
4.616msec. frame except for 0.577msec. pulse.
• Unevenness and distortion at the surface of PCB mounted module should be as small as possible.
• To protect devices from electro-static damage, soldering iron, measuring equipment and human body,
etc. should be grounded.
• To avoid the degradation of efficiency and output power, lead pins should not be floated from copper
foil of PCB, and connected to right position of RF signal line. (refer to figure 2)
• Recommendation to improve the thermal resistance is shown below.
— Make through holes as many as possible under module.
— Use heat sink on the top case of module.
• When the external components (Isolator, Duplexer, etc.) of the module are changed, the electrical
characteristics of total system should be evaluated enough.
• To avoid destruction of module caused by excess power consumption, voltage of APC should be
limited less than 6V.
• To get good stability, all GND pins should be soldered to ground pattern of PCB.
• Don’ t apply Full Heating Methods except Infrared Heating Methods.
• In case of Partial Heating Methods, soldering temperature and time should be less than 230°C, 10sec,
per each GND pin.
• Soldering temperature and time for I.R. Reflow should be the reflow profile shown in figure 2.
• Recommended conditions for Rising Methods shows as follows.
Solvents: de-ionized water, isopropyl alcohol, ethyl alcohol
Rising condition: in case of soak rising 5 Min Max, in case of ultrasonic rising 5 Min Max
• Don’ t apply dipping solder method to mount.
• Apply the way of washing after actual confirmation.
• Recommended pattern of footprint is shown in figure 3.
RF signal line
Worse
Better
module
module
PCB
All of lead pins should be connected just on the RF signal line.
Figure 1
PF0147
(°C)
Soldering
230
Natural-cooling
Pre-heating
160
140
–1[°C/s]
60 to 90s
30s Max
1[°C/s]
–4[°C/s]
4[°C/s]
Room
temp.
Package surface temperature (an example)
Figure 2 Recommended Reflow Profile
14.2
3.1
8.2
0.4
1.5
1.5
1.5
1.5
1.6
3.1
4.0
Package Surface Temperature
230°C Max
1 to 4[°C/s]
5.1
5.1
3.5
Unit: mm
Figure 3 Recommended Pattern of Footprint
PF0147
Characteristics Curve
VAPC, ηT, VSWR (in) vs. Frequency
3
50
5
Apc Voltage VAPC (V)
2
40
3
30
VAPC
20
2
VSWR
1.5
10
1
Pin = 10.4mW
VDD = 4.8V
Pout = 3.2W
1
0
870
885
900
915
0
930
Frequency f (MHz)
2nd H.D, 3rd H.D vs. Frequency
–30
–30
Pin = 10.4mW
VDD = 4.8V
Pout = 3.2W
2nd H.D (dB)
–40
–40
–50
2nd H.D
–50
–60
3rd H.D
–60
–70
–80
870
–70
885
900
Frequency f (MHz)
915
–80
930
3rd H.D (dB)
V.S.W.R. (in)
2.5
Efficiency ηT (%)
ηT
4
PF0147
Pout, ηT vs. VAPC (1)
50
5
f = 890MHz
Pin = 10.4mW
VDD = 4.8V
40
30
3
Pout
2
20
1
10
0
1
1.5
2
3
2.5
Efficiency ηT (%)
Output Power Pout (W)
4
ηT
0
3.5
Apc Voltage VAPC (V)
Pout, ηT vs. VAPC (2)
50
5
f = 915MHz
Pin = 10.4mW
VDD = 4.8V
40
3
30
Pout
2
20
1
10
0
1
1.5
2
2.5
Apc Voltage VAPC (V)
3
0
3.5
Efficiency ηT (%)
Output Power Pout (W)
4
ηT
PF0147
2nd H.D, 3rd H.D, VSWR (in) vs. VAPC (1)
3
–20
–20
–30
–30
–40
–40
2nd H.D
VSWR
–50
–50
3rd H.D (dBc)
2
2nd H.D (dBc)
V.S.W.R. (in)
2.5
3rd H.D
1.5
–60
1
–60
f = 890MHz
Pin = 10.4mW
VDD = 4.8V
–70
1
1.5
2
2.5
3
–70
3.5
Apc Voltage VAPC (V)
2nd H.D, 3rd H.D, VSWR (in) vs. VAPC (2)
3
–20
–20
–30
–30
2nd H.D (dBc)
V.S.W.R. (in)
2
2nd H.D
–40
–40
–50
–50
1.5
3rd H.D
f = 915MHz
Pin = 10.4mW
VDD = 4.8V
–60
1
–60
–70
1
1.5
2
2.5
Apc Voltage VAPC (V)
3
–70
3.5
3rd H.D (dBc)
VSWR
2.5
PF0147
Pout, ηT vs. Pin (1)
60
5
f = 890MHz
VDD = 4.8V
VAPC = 3.5V
50
ηT
3
40
2
30
1
20
0
5
6
7
8
9
10
11
12
13
14
Efficiency ηT (%)
Output Power Pout (W)
4
Pout
10
15
Input Power Pin (mW)
Pout, ηT vs. Pin (2)
60
5
f = 915MHz
VDD = 4.8V
VAPC = 3.5V
Pout
50
ηT
3
40
2
30
1
20
0
5
6
7
8
9
10
11
12
Input Power Pin (mW)
13
14
10
15
Efficiency ηT (%)
Output Power Pout (W)
4
PF0147
ηT, VAPC, VSWR (in) vs. Pin (1)
3
5
50
ηT
4
Efficiency ηT (%)
V.S.W.R. (in)
2
VSWR
VAPC
30
3
20
2
Apc Voltage VAPC (V)
40
2.5
1.5
10
1
1
f = 890MHz
VDD = 4.8V
Pout = 3.2W
0
5
6
7
8
9
10
11
12
13
14
0
15
Input Power Pin (mW)
ηT, VAPC, VSWR (in) vs. Pin (2)
3
5
50
40
4
30
3
2
Efficiency ηT (%)
V.S.W.R. (in)
2.5
VAPC
2
20
1.5
VSWR
10
1
1
f = 915MHz
VDD = 4.8V
Pout = 3.2W
0
5
6
7
8
9
10
11
12
Apc Voltage VAPC (V)
13
14
0
15
Apc Voltage VAPC (V)
ηT
PF0147
Package Dimensions
Unit: mm
(1.8)
(2.5)
2
3 4
(5.1) (5.1)
(2.5)
(0.3)
12 }0.5
(7.5)
(4 – 3.0)
1
3.0MAX.
2.35 }0.5
(1.5)
(17 )
(1.7 )
20 }0.3
(1.5)
(0.25)
(0.5)
Hitachi code
EIAJ code
JEDEC code
RF-H1
—
—