AW5015 产品手册
2016 年 4 月 V1.2
极低噪声系数,应用于全球导航卫星系统的低噪声放大器
特性
描述
采用专利的智能线性度增强技术(SLT)以
AW5015 是一款适用于 GPS,
格洛纳斯,
减轻射频环境干扰;
伽利略和北斗等全球导航卫星系统(GNSS)
极低的噪声系数:0.60dB;
的低噪声放大器。在射频端口内置隔直电容,
高功率增益:18.5dB;
所以输入端口无需另加电容,芯片可以尽量
高线性度 IIP3oob:+4.5dBm;
靠近天线,减少了线路损耗。其外围元器件
高输入 1dB 压缩点:-9.2dBm;
简单,只需要一个外置输入匹配电感,节省占
简单的 PCB 应用,只需一个外置的匹配电
板面积,是一款经济高效的解决方案。
感;
AW5015 采用专利的智能线性度增强技
输出内部匹配到 50 欧姆;
工作电压:1.5V~3.6V;
工作频率:1550~1615MHz;
纤小的 1.1mmX0.9mmX 0.45mm DFN 6L
术(SLT),具有极低噪声系数,高线性度,
高增益等特性,可支持低至 1.5V,高至 3.6V
的供电电压。所有这些特性使得 AW5015 成
为 GNSS 低噪声放大器的最佳选择,极低的
封装
噪声系数大大地改善了灵敏度,高线性度使
3kV HBM 静电保护(包括 RFIN 和 RFOUT
得系统能更好地抵抗带外干扰,并且降低了
引脚)
前级的滤波要求,进而降低了 GNSS 接收机
的总成本。
应用
AW5015 采用纤小的 1.1mm x 0.9 mm
手机、平板电脑、数码相机
个人导航设备、射频前端模组
完整的 GPS 芯片模组
防盗保护设备
x 0.45 mm DFN-6L 封装,额定的工作温度
范围为-40℃至 85℃。
引脚分布及标记图
顶视图
1
3
AX
2
底视图
6
6
1
5
5
2
4
4
3
Pin No.
Pin Name
1
GND
2
VCC
3
RFOUT
4
GNDRF
5
RFIN
6
EN
A---AW5015DNR;X---生产跟踪码
图 1.
AW5015 引脚分布及标识图
版权所有© 2016 上海艾为电子技术有限公司
第 1 页 共 23 页
AW5015 datasheet
Apr 2016 V1.2
Ultra-Low Noise Amplifier for Global Navigation
Satellite Systems (GNSS)
FEATURES
INTRODUCTION
The AW5015 is a Low Noise Amplifier
designed for Global Navigation Satellite
Systems (GNSS) as GPS, GLONASS, Galileo and Compass. With on-chip DC
blocking capacitors at RFIN and RFOUT,
The AW5015 can be close to the antenna,
requires only one external input matching
inductor, and reduces assembly complexity
and the PCB area, enabling a cost-effective
solution.
Reduce RF environment Interference
with patented Smart-Linearity-Technology (SLT);
Ultra low noise figure(NF)=0.60dB;
High power gain=18.5dB;
High linearity IIP3oob=+4.5dBm;
High input 1dB-compression point=
-9.2dBm;
Requires only one input matching
inductor;
RF output internally matched to 50 ohm;
Supply voltage: 1.5V to 3.6V;
Operating frequencies: 1550~1615MHz;
Slim DFN-6L package:1.1mmX0.9mmX
0.45mm
3kV HBM ESD protection (including
RFIN and RFOUT pin)
The AW5015 with patented Smart Linearity Technology (SLT) achieves ultra low
noise figure, high linearity, high gain, over a
wide range of supply voltages from 1.5V up
to 3.6V. All these features make AW5015
an excellent choice for GNSS LNA as it
improves sensitivity with low noise figure
and high gain, provide better immunity
against out-of-band jammer signals with
high linearity, reduces filtering requirement
of preceding stage and hence reduces the
overall cost of the GNSS receiver.
APPLICATIONS
Smart phones, feature phones,
Tablet PCs,
Personal Navigation Devices,
Digital Still Cameras, Digital Video Cameras;
RF Front End modules;
Complete GPS chipset modules;
Theft protection(laptop, ATM);
The AW5015 is available in a small
lead-free, RoHS-Compliant, 1.1mm x
0.9mm x 0.45mm 6-pin DFN package。
PIN CONFIGURATION AND MARKING
Top View
1
3
AX
2
Bottom View
6
6
1
5
5
2
4
4
3
Pin No.
Pin Name
1
GND
2
VCC
3
RFOUT
4
GNDRF
5
RFIN
6
EN
A---AW5015DNR;X---Manufactory trace No.
Figure 1.
AW5015 Pin Configuration and Marking
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 2 of 23
AW5015 datasheet
Apr 2016 V1.2
TYPICAL APPLICATION
AW5015
GND
RF
INPUT
4
3
5
2
RF
OUTPUT
RFOUT
VCC
RFIN
SUPPLY
VOLTAGE
L1
C1
(optional)
EN
LOGIC
CONTROL
6
1
BIAS
GND
L1=9.1nH
C1=1nF
Figure 2.
Application Schematic AW5015
For a list of components see Table 6 and Table 7.
ORDER INFORMATION
Table 1. Order Information
Part Number
Temperature
Package
RoHS
Mark
SPQ
AW5015DNR
-40℃~85℃
1.1mm x 0.9 mm x 0.45mm
DFN-6L
Yes
A
Tape and Reel
3000pcs/Reel
AW 5015
R : Tape& Reel
DN: DFN
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 3 of 23
AW5015 datasheet
Apr 2016 V1.2
ABSOLUTE MAXIMUM RATINGS 1)
Table 2 .
Limiting Values
Values
Parameter
Symbol
Unit
Min.
Typ.
Max.
VCC
-0.3
-
5.0
V
Voltage at pin EN
VEN
-0.3
-
5.0
V
Current into pin VCC
ICC
-
-
30
mA
PIN
-
-
10
dBm
Package thermal resistance
θJA
-
148.2
Junction temperature
TJ
-
-
150
℃
Storage temperature range
TSTG
-65
-
150
℃
Ambient temperature range
Tamb
-40
-
85
℃
-
260
-
℃
Supply Voltage at pin VCC
2)
RF input power
3)
Solder temperature(10s)
℃/W
ESD range
HBM
4)
±3000
V
Latch-up
+IT: +400
mA
-IT: -400
mA
Note1: Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device.
These are stress ratings only and functional operation of the device at these or any other conditions beyond those
indicated under “recommended operating conditions” is not implied. Exposure to absolute maximum rated conditions for extended periods may affect device reliability.
Standard:JEDEC
STANDARD
NO.78D NOVEMBER 2011
Note2: Warning: due to internal ESD diode protection, the applied DC voltage should not exceed 5.0V in order to
avoid excess current.
Note3: The RF input and RF output are AC coupled through internal DC blocking capacitor.
Note4: HBM standard: MIL-STD-883H Method 3015.8.
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 4 of 23
AW5015 datasheet
Apr 2016 V1.2
ELECTRICAL CHARACTERISTICS
Table 3 .
(AW5015 EVB
1)
Electrical Characteristics
; VCC=1.5 to 3.6V, TA=-40~+85℃, f=1550MHz to 1615MHz; Typical values are at VCC=2.8V and
TA=+25℃, f=1575.42MHz, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
1.5
-
3.6
V
1.0
μA
15.0
mA
DC ELECTRICAL CHARACTERISTICS
VCC
Supply Voltage
ISD
Shut-Down Current
EN=Low
ICC
Supply Current
EN=High
VEN
Digital Input-Logic High
VEN
Digital Input-Logic Low
6.9
0.80
V
0.45
V
AC ELECTRICAL CHARACTERISTICS
Gp
Power Gain
18.5
dB
RLin
Input Return Loss
7.0
dB
ISL
Reverse Isolation
31.2
dB
RLout
Output Return Loss
12.0
dB
NF
Noise Figure
0.60
dB
Kf
Stability factor
Pjam=-20dBm;
fjam=850MHz
0.96
dB
Pjam=-20dBm;
fjam= 1850MHz
1.45
dB
Pjam=-30dBm;
fjam=850MHz
0.64
dB
Pjam=-30dBm;
fjam= 1850MHz
0.69
dB
NFj
Zs=50 ohm;
No jammer
2)
f=20MHz…10GHz
Noise Figure with jammer
1.0
IP1dB
Inband input
1dB-compression point
f=1575.42MHz;
-9.2
dBm
IIP3oob
Out-of-band input
rd
3 -order intercept point
f1= 1712.7MHz;
f2=1850MHz;
Pin=-20dBm
+4.1
dBm
IIP3oob
Out-of-band input
rd
3 -order intercept point
f1= 1712.7MHz;
f2=1850MHz;
Pin=-30dBm
+4.5
dBm
IIP2oob
Out-of-band input
rd
2 -order intercept point
f1= 2400MHz;
f2=824.6MHz;
Pin=-20dBm
+7.7
dBm
IIP2oob
Out-of-band input
rd
2 -order intercept point
f1= 2400MHz;
f2=824.6MHz;
Pin=-30dBm
+7.7
dBm
H2-input
referred
LTE band-13 2
monic
f=787.76MHz;
Pin=-25dBm;
fH2=1575.52MHz
-66.1
dBm
nd
Har-
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 5 of 23
AW5015 datasheet
Apr 2016 V1.2
Table 3 . Characteristics……continued
1)
(AW5015 EVB ; VCC=1.5 to 3.6V, TA=-40~+85℃, f=1550MHz to 1615MHz; Typical values are at VCC=2.8V and
TA=+25℃, f=1575.42MHz, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
AC ELECTRICAL CHARACTERISTICS
ton
Turn-on time
toff
Turn-off time
3)
3)
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 6 of 23
2.2
µs
1.7
µs
AW5015 datasheet
Apr 2016 V1.2
Table 4 .
(AW5015 EVB
Electrical Characteristics
1)
;VCC=1.5 to 3.6V, TA=-40~+85℃, f=1550MHz to 1615MHz; Typical values are at VCC=1.8V and
TA=+25℃, f=1575.42MHz, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
1.5
-
3.6
V
1.0
μA
15.0
mA
DC ELECTRICAL CHARACTERISTICS
VCC
Supply Voltage
ISD
Shut-Down Current
EN=Low
ICC
Supply Current
EN=High
VEN
Digital Input-Logic High
VEN
Digital Input-Logic Low
6.2
0.80
V
0.45
V
AC ELECTRICAL CHARACTERISTICS
Gp
Power Gain
18.0
dB
RLin
Input Return Loss
6.5
dB
ISL
Reverse Isolation
31.0
dB
RLout
Output Return Loss
13.5
dB
NF
Noise Figure
0.61
dB
Kf
Stability factor
Pjam=-20dBm;
fjam=850MHz
1.01
dB
Pjam=-20dBm;
fjam= 1850MHz
1.49
dB
Pjam=-30dBm;
fjam=850MHz
0.67
dB
Pjam=-30dBm;
fjam= 1850MHz
0.71
dB
NFj
Zs=50 ohm;
No jammer
2)
f=20MHz…10GHz
Noise Figure with jammer
1.0
IP1dB
Inband input
1dB-compression point
f=1575.42MHz
-14.5
dBm
IIP3oob
Out-of-band input
rd
3 -order intercept point
f1= 1712.7MHz;
f2=1850MHz;
Pin=-20dBm;
-2.5
dBm
IIP3oob
Out-of-band input
rd
3 -order intercept point
f1= 1712.7MHz;
f2=1850MHz;
Pin=-30dBm;
-0.5
dBm
IIP2oob
Out-of-band input
rd
2 -order intercept point
f1= 824.6MHz;
f2=2400MHz;
Pin=-20dBm
+7.1
dBm
IIP2oob
Out-of-band input
rd
2 -order intercept point
f1= 824.6MHz;
f2=2400MHz;
Pin=-30dBm
+7.1
dBm
H2-input
referred
LTE band-13 2
monic
f=787.76MHz;
Pin=-25dBm;
fH2=1575.52MHz
-65.0
dBm
nd
Har-
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 7 of 23
AW5015 datasheet
Apr 2016 V1.2
Table 4 . Characteristics……continued
1)
(AW5015 EVB
;VCC=1.5 to 3.6V, TA=-40~+85℃, f=1550MHz to 1615MHz; Typical values are at VCC=1.8V and
TA=+25℃, f=1575.42MHz, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
AC ELECTRICAL CHARACTERISTICS
ton
Turn-on time
toff
Turn-off time
3)
3)
Note1: input matched to 50 ohm using a high quality-factor 9.1nH inductor.
Note2: 0.08dB PCB losses are subtracted.
Note3: Within 10% of the final gain.
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 8 of 23
2.2
µs
1.7
µs
AW5015 datasheet
Apr 2016 V1.2
TYPICAL OPERATING CHARACTERISTICS
(AW5015 EVB; Typical values are at Vcc=2.8V and TA=+25℃, fRFIN=1575.42MHz, unless otherwise noted.)
ICC
Noise Figure
12
1.2
(3)
10
1
(1)
6
0.8
NF(dB)
ICC(mA)
(3)
(2)
8
(2)
0.6
(1)
4
0.4
2
0.2
0
0
1
1.5
2
2.5
3
3.5
VCC(V)
1
Pi=-45dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
1.5
2
2.5
3
3.5
VCC(V)
Pi=-45dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 3. Supply current as a function of supply
voltage; typical values
Figure 4. Noise Figure as a function of supply
voltage; typical values
Noise Figure
Power Gain
19.5
1.6
(1)
19
1.4
(2)
18.5
1.2
18
(3)
1
NF(dB)
Gp (dB)
17.5
17
16.5
(3)
0.8
(2)
0.6
(1)
16
0.4
15.5
0.2
15
14.5
0
1
1.5
2
2.5
3
3.5
VCC(V)
Pi=-45dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
1000
1200
1400
1600
1800
2000
f(MHz)
VCC=1.8V; Pi=-45dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 5. Power Gain as a function of supply
voltage; typical values
Figure 6. Noise Figure as a function of frequency; typical values
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 9 of 23
AW5015 datasheet
Apr 2016 V1.2
Power Gain
Noise Figure
1.6
20
1.4
18
(2)
(3)
1.2
16
1
(3)
PG (dB)
NF(dB)
(1)
0.8
(2)
0.6
(1)
14
12
10
0.4
8
0.2
6
0
1000
1200
1400
1600
1800
1000
2000
f(MHz)
VCC=2.8V; Pi=-45dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
1200
1400
1600
Figure 8. Power Gain as a function of frequency;
typical values
Power Gain
Power Gain
19
22
(1)
(2)
(1)
18
(2)
17
18
2000
f(MHz)
VCC=1.8V; Pi=-45dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 7. Noise Figure as a function of frequency ; typical values
20
1800
(3)
(3)
16
PG (dB)
PG (dB)
16
14
12
15
14
13
10
12
8
11
10
6
1000
1200
1400
1600
1800
2000
f(MHz)
VCC=2.8V; Pi=-45dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 9. Power Gain as a function of frequency;
typical values
-35
-29
-23
-17
-11
-5
Pin(dBm)
VCC=1.8V; f=1575.42MHz.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 10. Power Gain as a function of input
power; typical values
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 10 of 23
AW5015 datasheet
Apr 2016 V1.2
Power Gain
Power Gain
20
19
(1)
18
(2)
17
(3)
(3)
16
(4)
19
18
15
PG (dB)
PG (dB)
17
16
(1)
(2)
(5)
14
13
15
12
14
11
13
10
9
12
-35
-29
-23
-17
-11
-35
-5
Pin(dBm)
-23
-17
-11
TA=+25℃; f=1575.42MHz.
(1) VCC=3.6V
(2) VCC=3.1V
(3) VCC=2.8V
(4) VCC=1.8V
(5) VCC=1.5V
VCC=2.8V; f=1575.42MHz.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 11. Power Gain as a function of input
power; typical values
-29
-5
Pin(dBm)
Figure 12. Power Gain as a function of input
power; typical values
out-of-band IIP3
out-of-band IIP3
6
1
5
0
(1)
-1
4
(1)
3
IIP3(dBm)
IIP3(dBm)
-2
(2)
-3
(3)
-4
(2)
2
1
(3)
0
-5
-1
-6
-2
-3
-7
-30
-28
-26
-24
-22
-20
-18
-16
-14 -12 -10
Pin(dBm)
-30
-28
-26
-24
-22
-20
-18
-16
-14 -12 -10
Pin(dBm)
VCC=1.8V; f1=1713MHz; f2=1851MHz.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
VCC=2.8V; f1=1713MHz; f2=1851MHz.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 13. out-of-band input IP3 as a function of
input power; typical values
Figure 14. out-of-band input IP3 as a function of
input power; typical values
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 11 of 23
AW5015 datasheet
Apr 2016 V1.2
out-of-band IIP2
out-of-band IIP2
13
11
(3)
(2)
7
(3)
11
9
9
(2)
5
IIP2 (dBm)
IIP2 (dBm)
7
(1)
3
(1)
5
3
1
1
-1
-1
-3
-3
-30
-28
-26
-24
-22
-20
-18
-16
-30
-14 -12 -10
Pin(dBm)
-28
-26
-24
-22
-20
-18
-16
-14 -12 -10
Pin(dBm)
VCC=1.8V; f1=824.6MHz; f2=2400MHz.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
VCC=2.8V; f1=824.6MHz; f2=2400MHz.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 15. out-of-band input IP2 as a function of
input power; typical values
Figure 16. out-of-band input IP2 as a function of
input power; typical values
Input Return Loss
Input Return Loss
0.00
0
-1.00
-1
-2.00
-2
-3
-4
(2)
-4.00
-5.00
Rlin (dB)
Rlin (dB)
-3.00
(3)
(2)
-5
(3)
-6
-6.00
-7
(1)
-7.00
(1)
-8
-8.00
-9
-9.00
-10
1000
1200
1400
1600
1800
2000
f(MHz)
VCC=1.8V; Pin=-35dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 17. Input return loss as a function of
frequency; typical values
1000
1200
1400
1600
1800
2000
f(MHz)
VCC=2.8V; Pin=-35dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 18. Input return loss as a function of
frequency; typical values
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 12 of 23
AW5015 datasheet
Apr 2016 V1.2
Input Return Loss
Output Return Loss
0
0
(5)
(4)
(3)
(2)
-1
-5
-2
-3
(5)
(4)
(3)
(2)
(1)
-5
-6
-10
RLout (dB)
Rlin (dB)
-4
(1)
-15
-20
-7
-8
-25
-9
-10
-30
1000
1200
1400
1600
1800
2000
f(MHz)
1000
TA=+25℃; Pin=-35dBm.
(1) VCC=1.5V
(2) VCC=1.8V
(3) VCC=2.8V
(4) VCC=3.1V
(5) VCC=3.6V
1400
1600
1800
2000
f(MHz)
TA=+25℃; Pin=-35dBm.
(1) VCC=1.5V
(2) VCC=1.8V
(3) VCC=2.8V
(4) VCC=3.1V
(5) VCC=3.6V
Figure 19. Input return loss as a function of
frequency; typical value
Figure 20. Output return loss as a function of
frequency; typical values
Output Return Loss
Output Return Loss
0
0
-5
(1)
(2)
(3)
-10
-15
(1)
(2)
(3)
-10
RLout (dB)
-5
RLout (dB)
1200
-15
-20
-20
-25
-30
-25
1000
1200
1400
1600
1800
2000
f(MHz)
VCC=1.8V; Pin=-35dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 21. Output return loss as a function of
frequency; typical values
1000
1200
1400
1600
1800
2000
f(MHz)
VCC=2.8V; Pin=-35dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 22. Output return loss as a function of
frequency; typical values
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 13 of 23
AW5015 datasheet
Apr 2016 V1.2
Isolation
-25
-25
-30
-30
(1)
(2)
(3)
(1)
(2)
(3)
-35
ISL (dB)
-35
ISL (dB)
Isolation
-40
-40
-45
-45
-50
-50
-55
-55
1000
1200
1400
1600
1800
2000
f(MHz)
VCC=1.8V; Pin=-35dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
1000
1200
Isolation
-30
ISL (dB)
-35
(5)
(4)
(3)
(2)
(1)
-40
-45
-50
-55
1400
1800
2000
f(MHz)
Figure 24. Isolation as a function of frequency;
typical values
-25
1200
1600
VCC=2.8V; Pin=-35dBm.
(1) TA=-25 ℃
(2) TA=+25℃
(3) TA=+85℃
Figure 23. Isolation as a function of frequency;
typical values
1000
1400
1600
1800
2000
f(MHz)
TA=+25℃; Pin=-35dBm.
(1) VCC=1.5V
(2) VCC=1.8V
(3) VCC=2.8V
(4) VCC=3.1V
(5) VCC=3.6V
Figure 25. Isolation as a function of frequency;
typical values
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 14 of 23
AW5015 datasheet
Apr 2016 V1.2
AW5015 APPLICATION BOARD
Figure 26.
Drawing of Application Board
Vias
Copper
35um
FR4
AW5015DNR_ application_ board_ sideview
Figure 27.
Application Board Cross-Section
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 15 of 23
AW5015 datasheet
Apr 2016 V1.2
TEST CIRCUITS
1. DC Characteristics test: including power supply, pin voltage, supply current, standby current
AW5015
GND
RF
INPUT
4
3
5
2
RF
OUTPUT
RFOUT
SUPPLY
A
VOLTAGE
VCC
RFIN
L1
C1
(optional)
LOGIC
CONTROL
EN
6
1
BIAS
V
GND
L1=9.1nH
C1=1nF
Figure 28.
Circuit for DC test
2. S Parameter test: including input return loss, output return loss, reverse isolation, forward
gain, 1dB gain compression.
RF
INPUT AW5015 EVB
RF
OUTPUT
NetWork Analyzer
Figure 29.
Circuit for S Parameter test
3. Noise Figure test: including noise figure, power gain.
RF
INPUT AW5015 EVB
Noise
Source
Figure 30.
RF
OUTPUT
NF Analyzer
Circuit for Noise Figure test
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 16 of 23
AW5015 datasheet
Apr 2016 V1.2
4. Intermodulation distortion test: including third-order intercept point.
Signal
Generator
Power
Combiner
RF
AW5015 EVB
INPUT
RF
OUTPUT Signal Analyzer
Signal
Generator
Figure 31.
Circuit for intermodulation distortion test
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 17 of 23
AW5015 datasheet
Apr 2016 V1.2
APPLICATION INFORMATIONS
2. The output of AW5015 is internally
matched to 50 ohm and a DC
blocking capacitor is integrated
on-chip, thus no external component is required at the output.
1.1 EN control
The AW5015 includes an internal
switch to turn off the entire chip:
apply logic high to EN to turn on,
and a logic low to shut down.
1.2 List of components
1. The AW5015 requires only one external inductor for input matching. If
the device/phone manufacturers
implement very good power supply
filtering on their boards, the bypass
capacitor mentioned in this application circuit may be optional. With
the capacitor we can get better
performance like a little higher gain
etc. The value is optimized for the
best gain, noise figure, return loss
performance. Typical value of inductor is 9.1nH, capacitor is 1nF.
For schematics see Figure2.
3. The AW5015 should be placed
close to the GPS antenna with the
input-matching inductor. Use 50ohm microstrip lines to connect RF
INPUT and RF OUTPUT. Bypass
capacitor should be located close to
the device. For long Vcc lines, it
may be necessary to add more
decoupling
capacitors.
Proper
grounding of the GND pins is very
important.
Table6 lists the recommended inductor types and values; Table 7 lists the recommended
capacitor types and values.
Table6: list of inductor
Part Number
Inductance
Q(min)
Units
nH
LQW15A
9.1
25
SDWL1005C
9.1
24
Q Test
Frequency
Supplier
Size
250
Murata
0402
250
Sunlord
0402
MHz
Table7: list of capacitor
Part Number
Capacitance
Rated Voltage
Units
pF
V
GRM155
1000
50
Supplier
Size
Murata
0402
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 18 of 23
AW5015 datasheet
Apr 2016 V1.2
PACKAGE INFORMATION
D
A
A
// bbb C
B
ccc C
A1
SEATING PLANE
M
1
PIN1 CORNER
E
A2
aaa C
TOP VIEW
SIDE VIEW
PIN1 ID
e
4
6xb
3
ddd M
eee
CAB
6xL
CONTROLLING DIEMENSION
MILLIMETER
MIN
NOM
MAX
0.50
A
0.40
0.45
0.00
--0.05
A1
0.25
0.30
A2
0.35
A3
0.150 REF
b
0.30
0.10
0.20
1.00
0.80
0.90
D
E
1.20
1.00
1.10
e
0.40 BSC
L
0.40
0.20
0.30
0.1
aaa
bbb
0.1
ccc
0.08
ddd
0.1
eee
0.1
L1
0.25
0.15
0.20
SYMBOL
1
6
CAB
L1
BOTTOM VIEW
Figure 32.
M
A3
Package Outline
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 19 of 23
AW5015 datasheet
Apr 2016 V1.2
TAPE&REEL DESCRIPTION
2.0±0.05
Φ1.55±0.05
B'
4.0±0.1
Pin1
Marking
8.0±0.3
3.5±0.05
1.75±0.1
0.25±0.05
1.22±0.05
A'
A
4.0±0.1
REF 5°
1.02±0.05
B
Φ0.55±0.05
0.6±0.05
Section A-A'
Figure 33. Tape & Reel
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 20 of 23
Section B-B'
AW5015 datasheet
Apr 2016 V1.2
REFLOW
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 21 of 23
AW5015 datasheet
Apr 2016 V1.2
FOOTPRINT INFORMATION
NSMD: Non-Solder Mask Defined pads
0.4mm
0.4mm
0.35mm
0.35mm
0.5mm
0.25mm
0.5mm
0.25mm
(stencil thickness 100um)
Copper
Stencil apertures
Solder mask
Figure 34.
Footprint
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 22 of 23
AW5015 datasheet
Apr 2016 V1.2
REVISION HISTORY
Table 8.
Revision history
Document ID
Release date
Change notice
AW5015_V1.2
2016-04
Added REFLOW NOTES
AW5015_V1.1
AW5015_V1.1
2015-12
Added Tape & Reel Description and corrected the marking location of Pin1
AW5015_V1.0
AW5015_V1.0
2014-04
Product data sheet
AW5015_V0.8
Supersedes
Updated typical operating characteristics with temperature variation
Added ESD characteristics
Added IIP2oob
Added Jammed noise figure
Added footprint information
Added revision history
AW5015_V0.8
2014-02
Preliminary data sheet
Updated electrical characteristics
Updated typical operating characteristics under TA=+25℃
AW5015_V0.7
2013-11
Preliminary data sheet
AW5015_V0.7
-
Notice:Shanghai Awinic Technology Co. ltd cannot assume responsibility for use of any
circuitry other than circuitry entirely embodied in an Awinic product. No circuit patent
licenses are implied. Awinic reserves the right to change the circuitry and specifications
without notice at any time.
Copyright © 2016 SHANGHAI AWINIC TECHNOLOGY CO., LTD
Page 23 of 23