AD8391ARZ [ADI]
IC DUAL LINE DRIVER, PDSO8, PLASTIC, SOIC-8, Line Driver or Receiver;型号: | AD8391ARZ |
厂家: | ADI |
描述: | IC DUAL LINE DRIVER, PDSO8, PLASTIC, SOIC-8, Line Driver or Receiver 驱动 光电二极管 接口集成电路 驱动器 |
文件: | 总20页 (文件大小:248K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
xDSL Line Driver
3 V to 12 V with Power-Down
a
AD8391
FEATURES
PIN CONFIGURATION
Ideal xDSL Line Driver for VoDSL or Low Power
Applications such as USB, PCMCIA, or PCI Based
Customer Premise Equipment (CPE)
High Output Voltage and Current Drive
340 mA Output Drive Current
8-Lead SOIC
(Thermal Coastline)
V
MID
ꢀV
ꢁV
1
2
3
4
8
7
6
5
IN1
IN2
V
S
S
Low Power Operation
PWDN
MID
ꢀ
ꢁ
3 V to 12 V Power Supply Range
1-Pin Logic Controlled Standby, Shutdown
Low Supply Current of 19 mA (Typical)
Low Distortion
–82 dBc SFDR, 12 V p-p into Differential 21 ꢂ @ 100 kHz
4.5 nV/√Hz Input Voltage Noise Density, 100 kHz
Out-of-Band SFDR = –72 dBc, 144 kHz to 500 kHz,
ZLINE = 100 ꢂ, PLINE = 13.5 dBm
ꢁ
ꢀ
+V
S
–V
V
S
V
1
2
OUT
OUT
AD8391
High Speed
40 MHz Bandwidth (–3 dB)
375 V/ꢃs Slew Rate
APPLICATIONS
VoDSL Modems
xDSL USB, PCI, PCMCIA Cards
Line Powered or Battery Backup xDSL Modems
PRODUCT DESCRIPTION
The AD8391 consists of two parallel, low cost xDSL line drive
amplifiers capable of driving low distortion signals while running on
both 3 V to 12 V single-supply or equivalent dual-supply rails. It is
primarily intended for use in single-supply xDSL systems where low
power is essential, such as line powered and battery backup systems.
Each amplifier output drives more than 250 mA of current while
maintaining –82 dBc of SFDR at 100 kHz on 12 V, outstanding
performance for any xDSL CPE application.
The AD8391 provides a flexible power-down feature consisting of
a 1-pin digital control line. This allows biasing of the AD8391 to
full power (Logic 1), standby (Logic three-state maintains low
amplifier output impedance), and shutdown (Logic 0 places
amplifier outputs in a high impedance state). PWDN is refer-
enced to –VS.
EMPTY BIN
25
137.5
250
FREQUENCY – kHz
Figure 1. Upstream Transit Spectrum with Empty Bin
at 45 kHz; Line Power = 12.5 dBm into 100 Ω
Fabricated on ADI’s high speed XFCB process, the high bandwidth
and fast slew rate of the AD8391 keep distortion to a minimum,
while dissipating a minimum of power. The quiescent current of the
AD8391 is low: 19 mA total static current draw. The AD8391
comes in a compact 8-lead SOIC “thermal coastline” package and
operates over the temperature range –40°C to +85°C.
REV. A
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, norforanyinfringementsofpatentsorotherrightsofthirdpartiesthat
may result from its use. No license is granted by implication or otherwise
under any patent or patent rights of Analog Devices. Trademarks and
registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700
Fax: 781/326-8703
www.analog.com
© 2003 Analog Devices, Inc. All rights reserved.
(@ 25ꢄC, VS = 12 V, RL = 10 ꢂ, VMID = VS/2, G = –2, RF = 909 ꢂ, RG = 453 ꢂ,
unless otherwise noted. See TPC 1 for Basic Circuit Configuration.)
AD8391–SPECIFICATIONS
Parameter
Conditions
Min
Typ
Max
Unit
DYNAMIC PERFORMANCE
–3 dB Bandwidth
G = –1, VOUT < 0.4 V p-p, RG = 909 Ω
G = –2, VOUT < 0.4 V p-p
VOUT < 0.4 V p-p
40
38
4
50
375
8
MHz
MHz
MHz
MHz
V/µs
ns
0.1 dB Bandwidth
Large Signal Bandwidth
Slew Rate
Rise and Fall Time
Settling Time
VOUT = 4 V p-p
V
OUT = 4 V p-p
VOUT = 4 V p-p
0.1%, VOUT = 2 V p-p
60
ns
NOISE/HARMONIC
PERFORMANCE
Distortion, G = –5 (RG = 178 Ω)
Second Harmonic
Third Harmonic
VOUT = 8 V p-p (Differential)
100 kHz, RL = 21 Ω
–82
–95
–70
–72
4.5
9
dBc
dBc
dBc
dBc
nV/√Hz
pA/√Hz
dB
100 kHz, RL = 21 Ω
MTPR (In-Band)
25 kHz to 138 kHz, RL = 21 Ω
144 kHz to 500 kHz, RL = 21 Ω
f = 100 kHz Differential
f = 100 kHz
SFDR (Out-of-Band)
Input Noise Voltage
Input Noise Current
Crosstalk
f = 1 MHz, G = –2, Output to Output
64
DC PERFORMANCE
Input Offset Voltage
VMID = +VS/2
TMIN to TMAX
VMID = Float
2
3
2
15
mV
mV
mV
mV
mV
MΩ
Input Offset Voltage Match
Transimpedance
0.25
0.35
10
2.6
TMIN to TMAX
∆VOUT = 5 V
INPUT CHARACTERISTICS
Input Resistance
Input Bias Current
Input Bias Current Match
CMRR
Input CM Voltage Range
VMID Accuracy
VMID Input Resistance
VMID Input Capacitance
125
2.5
0.5
Ω
In1, In2 pins
In1 – In2
VMID = VIN = 5.5 V to 6.5 V, ∆VOS /∆VIN, cm
10
6
µA
µA
dB
V
48
1.2 to 10.8
VMID = Float Delta from +VS/2
5
2.5
10
30
mV
kΩ
pF
OUTPUT CHARACTERISTICS
Output Resistance
Output Resistance
Output Voltage Swing
Linear Output Current
Short-Circuit Current
Frequency = 100 kHz, PWDN 1
Frequency = 100 kHz, PWDN 0
RLOAD = 100 Ω
0.3
3
Ω
kΩ
V
0.1
16
11.9
21
SFDR < –75 dBc, f = 100 kHz, RL = 21 Ω
340
1500
mA
mA
POWER SUPPLY
Supply Current
PWDN = 1
TMIN to TMAX
PWDN = Open or Three-State
PWDN = 0
Single Supply
19
22
10
4
mA
mA
mA
mA
V
STBY Supply Current
SHUTDOWN Supply Current
Operating Range
6
12
3.0
Power Supply Rejection Ratio
VMID = VS /2, ∆VS = 0.5 V
55
dB
LOGIC INPUT (PWDN)
Logic 1 Voltage
Logic 0 Voltage
–VS + 2.0
V
V
–VS + 0.8
Logic Input Bias Current
Turn-On Time
300
200
µA
ns
RL = 21 Ω, IS = 90% of Typical
Specifications subject to change without notice.
–2–
REV. A
AD8391
(@ 25ꢄC, VS = 3 V, RL = 10 ꢂ, VMID = VS/2, G = –2, RF = 909 ꢂ, RG = 453 ꢂ, unless otherwise noted.
SPECIFICATIONS See TPC 1 for Basic Circuit Configuration.)
Parameter
Conditions
Min
Typ
Max
Unit
DYNAMIC PERFORMANCE
–3 dB Bandwidth
G = –1, VOUT < 0.4 V p-p
G = –2, VOUT < 0.4 V p-p
VOUT < 0.4 V p-p
37
36
3.5
30
50
15
110
MHz
MHz
MHz
MHz
V/µs
ns
0.1 dB Bandwidth
Large Signal Bandwidth
Slew Rate
Rise and Fall Time
Settling Time
V
OUT = 2 V p-p
VOUT = 2 V p-p
Differential, VOUT = 1 V p-p
0.1%, VOUT = 2 V p-p
ns
NOISE/HARMONIC
PERFORMANCE
Distortion
Second Harmonic
Third Harmonic
Input Noise Voltage
Input Noise Current
VOUT = 4 V p-p (Differential)
100 kHz, RL = 21 Ω
100 kHz, RL = 21 Ω
f = 100 kHz Differential
f = 100 kHz
–81
–97
4.5
9
dBc
dBc
nV/√Hz
pA/√Hz
DC PERFORMANCE
Input Offset Voltage
VMID = +VS/2
TMIN to TMAX
3
4
3
0.1
0.2
8
15
mV
mV
mV
mV
mV
MΩ
V
MID = Float
Input Offset Voltage Match
Transimpedance
2.6
TMIN to TMAX
∆VOUT = 1 V
INPUT CHARACTERISTICS
Input Resistance
Input Bias Current
Input Bias Current Match
CMRR
Input CM Voltage Range
VMID Accuracy
VMID Input Resistance
VMID Input Capacitance
125
Ω
In1, In2 pins
1
7
4
µA
µA
dB
V
In1 – In2
0.5
VMID
=
VIN = 1.3 V to 1.5 V, ∆VOS /∆VIN, cm
48
1.2 to 2.1
5
2.5
10
VMID = Float, Delta from +VS/2
30
mV
kΩ
pF
OUTPUT CHARACTERISTICS
Output Resistance
Output Resistance
Output Voltage Swing
Linear Output Current
Short-Circuit Current
Frequency = 100 kHz, PWDN 1
Frequency = 100 kHz, PWDN 0
RL = 100 Ω
0.2
9
Ω
kΩ
0.1
13
2.9
18
V
mA
mA
SFDR < –82 dBc, f = 100 kHz, RL = 21 Ω
125
1000
POWER SUPPLY
Supply Current
PWDN = 1
TMIN to TMAX
PWDN = Open or Three-State
PWDN = 0
Single Supply
16
19
8
mA
mA
mA
mA
V
STBY Supply Current
SHUTDOWN Supply Current
Operating Range
1
2
12
3.0
Power Supply Rejection Ratio
VMID = VS/2, ∆VS = 0.5 V
55
dB
LOGIC INPUTS (PWDN [1,0])
Logic 1 Voltage
–VS + 2.0
V
Logic 0 Voltage
Logic Input Bias Current
Turn-On Time
–VS + 0.8
V
µA
ns
60
200
RL = 21 Ω, IS = 90% of Typical
Specifications subject to change without notice.
–3–
REV. A
AD8391
ABSOLUTE MAXIMUM RATINGS1
MAXIMUM POWER DISSIPATION
The maximum power that can be safely dissipated by the
AD8391 is limited by the associated rise in junction temperature.
The maximum safe junction temperature for a plastic encapsu-
lated device is determined by the glass transition temperature of
the plastic, approximately 150°C. Temporarily exceeding this
limit may cause a shift in parametric performance due to a change
in the stresses exerted on the die by the package.
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.6 V
Internal Power Dissipation2
Small Outline Package (R) . . . . . . . . . . . . . . . . . . . 650 mW
Input Voltage (Common-Mode) . . . . . . . . . . . . . . . . . . . . VS
Logic Voltage, PWDN . . . . . . . . . . . . . . . . . . . . . . . . . . . . VS
Output Short-Circuit Duration
. . . . . . . . . . . . . . . . . . . . . Observe Power Derating Curve
Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C
Operating Temperature Range . . . . . . . . . . . –40°C to +85°C
Lead Temperature Range (Soldering 10 sec) . . . . . . . . . 300°C
To ensure proper operation, it is necessary to observe the maxi-
mum power derating curve.
2.0
NOTES
T
= 150ꢄC
J
1 Stresses above those listed under Absolute Maximum Ratings may cause perma-
nent damage to the device. This is a stress rating only; functional operation of the
device at these or any other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute maximum rating
conditions for extended periods may affect device reliability.
2 Specification is for device on a 4-layer board in free air at 85°C: 8-Lead SOIC
package: JA = 100°C/W.
1.5
1.0
0.5
0
8-LEAD SOIC PACKAGE
–50 –40 –30 –20 –10
0
10 20 30 40 50 60 70 80 90
AMBIENTTEMPERATURE – ꢄC
Figure 2. Plot of Maximum Power Dissipation
vs. Temperature
ORDERING GUIDE
Temperature
Range
Package
Description
Package
Option
Model
AD8391AR
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
8-Lead SOIC
8-Lead SOIC
8-Lead SOIC
Evaluation Board
R-8
R-8
R-8
AD8391AR–REEL
AD8391AR–REEL7
AD8391AR–EVAL
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection. Although
the AD8391 features proprietary ESD protection circuitry, permanent damage may occur on
devices subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are
recommended to avoid performance degradation or loss of functionality.
–4–
REV. A
Typical Performance Characteristics–AD8391
0.4
V
= ꢅ1.5V
C
S
F
G = –2
= 10ꢂ
0.3
0.2
C
= 0pF
R
F
L
R
R
F
G
V
OUT
V
IN
R
~
L
0.1
C
= 3pF
F
0
V
MID
0.1ꢃF
–0.1
–0.2
–0.3
–0.4
+V
–V
S
+
+
6.8ꢃF
6.8ꢃF
0.1ꢃF
0.1ꢃF
S
0
0
0
25
50
75
100 125 150 175 200 225 250
TIME – ns
TPC 4. Small Signal Step Response
TPC 1. Single-Ended Test Circuit
2.0
1.5
0.4
V
= ꢅ1.5V
V
= ꢅ6V
S
S
G = –2
= 10ꢂ
G = –2
= 10ꢂ
0.3
0.2
R
C
= 0pF
R
L
F
L
C
= 0pF
F
1.0
0.5
0.1
C
= 3pF
F
C
= 3pF
F
0
0
–0.5
–1.0
–1.5
–2.0
–0.1
–0.2
–0.3
–0.4
25
50
75
100 125 150 175 200 225 250
TIME – ns
0
25
50
75
100 125 150 175 200 225 250
TIME – ns
TPC 5. Large Signal Step Response
TPC 2. Small Signal Step Response
0.01
0.008
0.006
0.004
0.002
0
4
3
V
= ꢅ6V
V
= ꢅ6V
S
S
G = –2
= 10ꢂ
G = –2
C
= 0pF
F
R
L
2
C
= 3pF
V
= 1V p-p
F
IN
1
0
–0.002
–0.004
–0.006
–0.008
–0.01
–1
–2
–3
–4
OUTPUT ERROR
50
100
150
TIME – ns
200
250
300
0
25
50
75
100 125 150 175 200 225 250
TIME – ns
TPC 3. Large Signal Step Response
TPC 6. 0.1% Settling Time
–5–
REV. A
AD8391
12
6
3
0
V
R
= ꢅ6V
= 10ꢂ
V
R
= ꢅ1.5V
= 10ꢂ
S
S
9
L
L
G = –2
G = –2
6
3
–3
–6
0
–9
–3
–6
–9
–12
–15
–18
–12
–15
–18
–21
–24
0.1
1
10
100
1000
0.1
1
10
100
1000
FREQUENCY – MHz
FREQUENCY – MHz
TPC 7. Output Voltage vs. Frequency
TPC 10. Output Voltage vs. Frequency
1500
1250
1200
1000
V
= ꢅ6V
V
= ꢅ1.5V
S
S
V
@+85ꢄC
@+25ꢄC
@–40ꢄC
V
@
+85ꢄC
+25ꢄC
OH
OH
V
V
@ –40ꢄC
V
@
OH
OL
OH
V
V
@–40ꢄC
OH
1000
750
800
600
400
OH
500
V
@+85ꢄC
OL
V
@+25ꢄC
@–40ꢄC
OL
250
0
200
0
V
@
+25ꢄC
+85ꢄC
OL
V
OL
V
@
OL
0
100 200 300 400 500 600 700 800 900 1000
LOAD CURRENT – mA
0
50
100 150 200 250 300 350 400 450 500
LOAD CURRENT – mA
TPC 11. Output Saturation Voltage vs. Load
TPC 8. Output Saturation Voltage vs. Load
18
18
V
R
= ꢅ6V
= 10ꢂ
V
R
= ꢅ1.5V
= 10ꢂ
S
S
15
12
9
15
12
9
L
L
G = ꢀ2
G = ꢀ2
STANDBY
STANDBY
6
6
3
3
0
FULL POWER
0
FULL POWER
–3
–6
–9
–3
–6
–9
0.1
1
10
FREQUENCY – MHz
100
1000
0.1
1
10
FREQUENCY – MHz
100
1000
TPC 12. Small Signal Frequency Response
TPC 9. Small Signal Frequency Response
–6–
REV. A
AD8391
60
50
40
30
20
10
0
140
120
V
= ꢅ1.5V
S
V
= ꢅ6V
100
80
60
40
20
0
S
V
= ꢅ1.5V
S
V
= ꢅ6V
S
10
100
1k
10k
100k
1M
10
100
1k
10k
100k
1M
FREQUENCY – Hz
FREQUENCY – Hz
TPC 13. Voltage Noise vs. Frequency (RTI)
TPC 16. Current Noise vs. Frequency (RTI)
10k
1k
10k
1k
V
= ꢅ6V
S
V
= ꢅ1.5V
S
POWER-DOWN
POWER-DOWN
100
10
100
10
POWER-UP
1
POWER-UP
1
0.1
0.01
0.1
0.01
0.1
1
10
100
1000
0.1
1
10
100
1000
FREQUENCY – MHz
FREQUENCY – MHz
TPC 17. Output Impedance vs. Frequency
TPC 14. Output Impedance vs. Frequency
–15
–20
–25
–30
–35
–40
–45
20
V
R
= ꢅ6V
= 10ꢂ
S
L
POWER-DOWN
= 10dBm
0
–20
V
IN
POWER-UP
–40
G = –5, R = 178ꢂ, R = 909ꢂ
G
F
–60
–80
V
= 10dBm
= ꢅ6V
= 10ꢂ
IN
V
R
G = –2, R = 453ꢂ, R = 909ꢂ
S
G
F
POWER-DOWN
L
–100
–120
G = –2
–50
–55
0.1
1
10
FREQUENCY – MHz
100
1000
0.1
1
10
FREQUENCY – MHz
100
1000
TPC 18. Signal Feedthrough vs. Frequency
TPC 15. Crosstalk (Output to Output)
vs. Frequency
REV. A
–7–
AD8391
–30
–40
–50
–60
–70
–80
–90
R
R
F
G
R
= 21ꢂ
L
FORV = ꢅ6V, V
= 8V p-p
= 2V p-p
OUT
S
OUT
V
IN+
FORV = ꢅ1.5V, V
S
G = –5
V
OUT–
V
MID
R
HD2@V = ꢅ1.5V
L
S
C
MID
HD2@V = ꢅ6V
S
V
OUT+
R
R
F
G
HD3@V = ꢅ1.5V
S
–100
–110
V
IN–
HD3@V = ꢅ6V
S
0.01
0.1
1
10
FREQUENCY – MHz
TPC 19. Differential Output Test Setup
TPC 22. Differential Distortion vs. Frequency
–30
–40
–30
V
R
= ꢅ6V
= 21ꢂ
V
R
= ꢅ1.5V
= 21ꢂ
S
S
–40
–50
L
L
G = –5, (R = 178ꢂ)
G = –5, (R = 178ꢂ)
G
G
HD3 (F = 500kHz)
–50
O
–60
–60
HD2 (F = 500kHz)
O
HD2 (F = 500kHz)
O
–70
–70
HD3 (F = 500kHz)
O
–80
–80
HD2 (F = 100kHz)
–90
–90
HD2 (F = 100kHz)
O
O
–100
–110
HD3 (F = 100kHz)
–100
–110
O
HD3 (F = 100kHz)
O
2
6
10
14
18
22
0
1
2
3
4
5
6
OUTPUTVOLTAGE –V p-p
OUTPUTVOLTAGE –V p-p
TPC 20. Differential Distortion vs. Output Voltage
TPC 23. Differential Distortion vs. Output Voltage
–50
–25
V
= ꢅ6V
S
V
R
= ꢅ6V
S
R
= 100ꢂ
LINE
= 100ꢂ
LINE
–55
–60
–65
–70
–75
–80
–35
–45
–55
–65
–75
–85
14dBm
13.5dBm
13.5dBm
14dBm
13dBm
13dBm
12.5dBm 12dBm
12.5dBm 12dBm
1.7
1.8
1.9
2.0
2.1
2.2
2.3
1.7
1.8
1.9
2.0
2.1
2.2
2.3
TRANSFORMERTURNS RATIO
TRANSFORMERTURNS RATIO
TPC 21. MTPR vs. Transformer Turns Ratio
TPC 24. SFDR vs. Transformer Turns Ratio
–8–
REV. A
AD8391
–30
–40
–30
–40
V
= ꢅ6V
V = ꢅ1.5V
S
S
G = –5, (R = 178ꢂ)
G = –5, (R = 178ꢂ)
G
G
HD3 (F = 500kHz)
O
HD2 (F = 500kHz)
O
–50
–50
HD3 (F = 500kHz)
O
–60
–60
HD2 (F = 500kHz)
O
–70
–70
–80
–80
HD2 (F = 100kHz)
O
–90
–90
HD2 (F = 100kHz)
O
–100
–110
–100
HD3 (F = 100kHz)
O
HD3 (F = 100kHz)
O
–110
25
150
275
400
525
650
25
75
125
175
225
275
PEAK OUTPUT CURRENT – mA
PEAK OUTPUT CURRENT – mA
TPC 25. Single-Ended Distortion vs. Peak
Output Current
TPC 27. Single-Ended Distortion vs. Peak
Output Current
V
V
= ꢅ6V
V
V
= ꢅ1.5V
S
S
= 1V/DIV
= 500mV/DIV
= 500mV/DIV
IN
IN
V
= 2V/DIV
V
OUT
OUT
G = –5
R
G = –5
= 10ꢂ
R
= 10ꢂ
L
L
V
V
OUT
OUT
0V
0V
V
V
IN
IN
0V
0V
TIME – ns (100ns/DIV)
TIME – ns (100ns/DIV)
TPC 26. Overload Recovery
TPC 28. Overload Recovery
REV. A
–9–
AD8391
GENERAL INFORMATION
Theory of Operation
The AD8391 is a dual current feedback amplifier with high
output current capability. It is fabricated on Analog Devices’
proprietary eXtra Fast Complementary Bipolar Process (XFCB) that
enables the construction of PNP and NPN transistors with fT’s
greater than 3 GHz. The process uses dielectrically isolated
transistors to eliminate the parasitic and latch-up problems caused
by junction isolation. These features enable the construction of
high frequency, low distortion amplifiers.
V
O
BIAS
V
V
P
N
The AD8391 has a unique pin out. The two noninverting inputs
of the amplifier are connected to the VMID pin, which is internally
biased by two 5 kΩ resistors forming a voltage divider between
+VS and –VS. VMID is accessible through Pin 7. There is also a
10 pF internal capacitor from VMID to –VS. The two inverting pins
are available at Pin 1 and Pin 8, allowing the gain of the amplifiers to
be set with external resistors. See Page 1 for a connection diagram
of the AD8391.
Figure 3. Simplified Schematic
A simplified schematic of an amplifier is shown in Figure 3.
Emitter followers buffer the positive input, VP, to provide low
input current and current noise. The low impedance current
feedback summing junction is at the negative input, VN. The
output stage is another high gain amplifier used as an integrator
to provide frequency compensation. The complementary common-
emitter output provides the extended output swing.
G = 1
+
V
O
V
IN
R
I
I
= I
C
R
T
IN
IN
T
IN
T
+
–
V
OUT
–
A current feedback amplifier’s bandwidth and distortion perfor-
mance are relatively insensitive to its closed-loop signal gain,
which is a distinct advantage over a voltage-feedback architecture.
Figure 4 shows a simplified model of a current feedback amplifier.
The feedback signal is an error current that flows into the inverting
node. RIN is inversely proportional to the transconductance of
the amplifier’s input stage, gmi. Circuit analysis of the pictured
follower with gain circuit yields:
R
F
R
G
Figure 4. Model of Current Feedback Amplifier
Feedback Resistor Selection
VOUT
VIN
G × Tz s
( )
In current feedback amplifiers, selection of the feedback and
gain resistors will impact distortion, bandwidth, noise, and gain
flatness. Care should be exercised in the selection of these resistors
so that the optimum performance is achieved. Table I shows the
recommended resistor values for use in a variety of gain settings for
the test circuits in TPC 1 and TPC 19. These values are only
intended to be a starting point when designing for any application.
=
Tz s + R + G × R
( )
F
IN
where:
RF
G = 1+
RG
RF
Tz s =
( )
Table I. Resistor Selection Guide
1 + sCT (RT )
Gain
RF (ꢂ)
RG (ꢂ)
1
RIN
≅ 125 Ω
gmi
=
–1
–2
–3
–4
–5
909
909
909
909
909
909
453
303
227
178
Recognizing that G × RIN << RF , and that the –3 dB point is set
when Tz(s) = RF, one can see that the amplifier’s bandwidth
depends primarily on the feedback resistor. There is a value of
RF below which the amplifier will be unstable, as the amplifier
will have additional poles that will contribute excess phase shift.
The optimum value for RF depends on the gain and the amount
of peaking tolerable in the application. For more information
about current feedback amplifiers, see ADI’s high speed design
techniques at www.analog.com/technology/amplifiersLinear/
designTools/evaluationBoards/pdf/1.pdf
.
–10–
REV. A
AD8391
Power-Down Feature
Power Dissipation
A three-state power-down function is available via the PWDN pin.
It allows the user to select among three operating conditions: full on,
standby, or shutdown. The –VS pin is the logic reference for the
PWDN function. The full shutdown state is maintained when the
PWDN is at 0.8 V or less above –VS. In shutdown the AD8391 will
draw only 4 mA. If the PWDN pin floats, the AD8391 operates in
a standby mode with low impedance outputs and draws approxi-
mately 10 mA.
It is important to consider the total power dissipation of the
AD8391 to size the heat sink area of an application properly.
Figure 5 is a simple representation of a differential driver. With
some simplifying assumptions the total power dissipated in this
circuit can be estimated. If the output current is large compared to
the quiescent current, computing the dissipation in the output
devices and adding it to the quiescent power dissipation will give
a close approximation of the total power dissipation in the pack-
age. A factor α corrects for the slight error due to the Class A/B
operation of the output stage. The value of α depends on what
portion of the quiescent current is in the output stage and varies
Power Supply and Decoupling
The AD8391 can be powered with a good quality (i.e., low noise)
supply anywhere in the range from 3 V to 12 V. The AD8391
can also operate on dual supplies, from 1.5 V to 6 V. In order
to optimize the ADSL upstream drive capability of +13 dBm and
maintain the best spurious free dynamic range (SFDR), the
AD8391 circuit should be powered with a well-regulated supply.
from 0 to 1. For the AD8391, α
≅
0.72.
+V
S
+V
S
Careful attention must be paid to decoupling the power supply.
High quality capacitors with low equivalent series resistance
(ESR), such as multilayer ceramic capacitors (MLCCs), should
be used to minimize supply voltage ripple and power dissipation.
In addition, 0.1 µF MLCC decoupling capacitors should be located
no more than 1⁄8 inch away from each of the power supply pins.
A large, usually tantalum, 10 µF capacitor is required to provide
good decoupling for lower frequency signals and to supply current
for fast, large signal changes at the AD8391 outputs.
+V
O
–V
O
R
L
–V
–V
S
S
Bypassing capacitors should be laid out in such a manner to keep
return currents away from the inputs of the amplifiers. This will
minimize any voltage drops that can develop due to ground cur-
rents flowing through the ground plane. A large ground plane
will also provide a low impedance path for the return currents.
Figure 5. Simplified Differential Driver
Remembering that each output device only dissipates power for
half the time gives a simple integral that computes the power for
each device:
The VMID pin should also be decoupled to ground by using a 0.1 µF
ceramic capacitor. This will help prevent any high frequency
components from finding their way to the noninverting inputs of
the amplifiers.
1
2
2V
RL
O
(VS –VO )×
∫
The total supply power can then be computed as:
Design Considerations
1
RL
2
There are some unique considerations that must be taken into
account when designing with the AD8391. The VMID pin is internally
biased by two 5 kΩ resistors forming a voltage divider between
VCC and ground. These resistors will contribute approximately
6.3 nV/√Hz of input-referred (RTI) noise. This noise source is
common mode and will not contribute to the output noise when
the AD8391 is used differentially. In a single-supply system,
this is unavoidable. In a dual-supply system, VMID can be connected
directly to ground, eliminating this source of noise.
P
= 4 VS |V | − V
×
+ 2 α IQ VS
∫
∫
TOT
(
O
O
)
In this differential driver, VO is the voltage at the output of one
amplifier, so 2 VO is the voltage across RL. RL is the total imped-
ance seen by the differential driver, including any back termination.
Now, with two observations the integrals are easily evaluated.
First, the integral of VO2 is simply the square of the rms value of
VO. Second, the integral of |VO| is equal to the average rectified
value of VO, sometimes called the mean average deviation, or
MAD. It can be shown that for a DMT signal, the MAD value
is equal to 0.8 times the rms value:
When VMID is left floating, a change in the power supply voltage
(∆V) will result in a change of one-half ∆V at the VMID pin. If
the amplifiers’ inverting inputs are ac-coupled, one-half ∆V will
appear at the output, resulting in a PSRR of –6 dB. If the inputs
are dc-coupled, ∆V × (1 + RF /RG) will appear at the outputs.
1
P
= 4(0.8VO rmsVS –VO rms2 )×
+ 2 α IQ VS
TOT
RL
For the AD8391 operating on a single 12 V supply and delivering
a total of 16 dBm (13 dBm to the line and 3 dBm to account for
the matching network) into 50 Ω (100 Ω reflected back through
a 1:2 transformer plus back termination), the dissipated power
is 395 mW.
REV. A
–11–
AD8391
Using these calculations and a θJA of 100°C/W for the SOIC,
Table II shows junction temperature versus power delivered to
the line for several supply voltages while operating at an ambient
temperature of 85°C. Operation at a junction temperature over
the absolute maximum rating of 150°C should be avoided.
Evaluation Board
The AD8391 is available installed on an evaluation board.
Figure 10 shows the schematics for the evaluation board. AC-
coupling capacitors of 0.1 µF, C6 and C11, in combination with
10 kΩ, resistors R25 and R26, will form a first-order high-pass
pole at 160 Hz.
The bill of materials included as Table III represents the com-
ponents that are installed in the evaluation board when it is
shipped to a customer. There are footprints for additional components,
such as an AD8138, that will convert a single-ended signal into a
differential signal. There is also a place for an AD9632, which can
be used to convert a differential signal into a single-ended signal.
Table II. Junction Temperature vs. Line Power
and Operating Voltage for SOIC at 85ꢄC Ambient
VSUPPLY
PLINE, dBm
12
12.5
13
14
15
125
127
129
126
129
131
Transformer Selection
Customer premise ADSL requires the transmission of a 13 dBm
(20 mW) DMT signal. The DMT signal has a crest factor of 5.3,
requiring the line driver to provide peak line power of 560 mW.
560 mW peak line power translates into a 7.5 V peak voltage on a
100 Ω telephone line. Assuming that the maximum low distortion
output swing available from the AD8391 line driver on a 12 V
supply is 11 V, and taking into account the power lost due to the
termination resistance, a step-up transformer with a turns ratio
of 1:2 is adequate for most applications. If the modem designer
desires to transmit more than 13 dBm down the twisted pair, a
higher turns ratio can be used for the transformer. This trade-off
comes at the expense of higher power dissipation by the line
driver as well as increased attenuation of the downstream signal
that is received by the transceiver.
Thermal stitching, which connects the outer layers to the internal
ground plane(s), can help to use the thermal mass of the PCB to
draw heat away from the line driver and other active components.
Layout Considerations
As is the case with all high speed applications, careful attention
to printed circuit board layout details will prevent associated
board parasitics from becoming problematic. Proper RF design
techniques are mandatory. The PCB should have a ground plane
covering all unused portions of the component side of the board
to provide a low impedance return path. Removing the ground
plane on all layers from the areas near the input and output pins
will reduce stray capacitance, particularly in the area of the
inverting inputs. The signal routing should be short and direct in
order to minimize parasitic inductance and capacitance associated
with these traces. Termination resistors and loads should be located
as close as possible to their respective inputs and outputs.
Input and output traces should be kept as far apart as possible
to minimize coupling (crosstalk) through the board. Wherever
there are complementary signals, a symmetrical layout should be
provided to the extent possible to maximize balanced perfor-
mance. When running differential signals over a long distance, the
traces on the PCB should be close. This will reduce the radiated
energy and make the circuit less susceptible to RF interference.
Adherence to stripline design techniques for long signal traces
(greater than about one inch) is recommended.
In the simplified differential drive circuit shown in Figure 6, the
AD8391 is coupled to the phone line through a step-up transformer
with a 1:2 turns ratio. R45 and R46 are back termination or line
matching resistors, each 12.5 Ω [1/2 (100 Ω/22 )] where 100 Ω is
the approximate phone line impedance. A transformer reflects
impedance from the line side to the IC side as a value inversely
proportional to the square of the turns ratio. The total differential
load for the AD8391, including the termination resistors, is 50 Ω.
Even under these conditions, the AD8391 provides low distor-
tion signals to within 0.5 V of the power supply rails.
One must take care to minimize any capacitance present at the
outputs of a line driver. The sources of such capacitance can
include but are not limited to EMI suppression capacitors,
overvoltage protection devices, and the transformers used in the
hybrid. Transformers have two kinds of parasitic capacitances:
distributed or bulk capacitance and interwinding capacitance.
Distributed capacitance is a result of the capacitance created
between each adjacent winding on a transformer. Interwinding
capacitance is the capacitance that exists between the windings
on the primary and secondary sides of the transformer. The
existence of these capacitances is unavoidable and limiting both
distributed and interwinding capacitance to less than 20 pF each
should be sufficient for most applications.
453ꢂ 909ꢂ
12.5ꢂ
1:2
+
1ꢃF
0.1ꢃF
8
7
6
5
+V
S
R
V
L
IN
V
MID
AD8391
It is also important that the transformer operates in its linear
region throughout the entire dynamic range of the driver.
Distortion introduced by the transformer can severely degrade
DSL performance, especially when operating at long loop lengths.
–V
S
1
2
3
4
+3V
–
453ꢂ 909ꢂ
12.5ꢂ
+
–
1ꢃF
0.1ꢃF
10ꢃF
+
V
CC
Figure 6. Single-Supply Voltage Differential Drive Circuit
–12–
REV. A
AD8391
Receive Channel Considerations
Conventional methods of expressing the output signal integrity of
line drivers, such as single-tone harmonic distortion or THD,
two-tone intermodulation distortion (IMD) and third-order
intercept (IP3) become significantly less meaningful when ampli-
fiers are required to process DMT and other heavily modulated
waveforms. A typical ADSL upstream DMT signal can contain
as many as 27 carriers (subbands or tones) of QAM signals.
Multitone power ratio (MTPR) is the relative difference between
the measured power in a typical subband (at one tone or carrier)
versus the power at another subband specifically selected to
contain no QAM data. In other words, a selected subband (or
tone) remains open or void of intentional power (without a QAM
signal) yielding an empty frequency bin. MTPR, sometimes
referred to as the empty bin test, is typically expressed in dBc,
similar to expressing the relative difference between single-tone
fundamentals and second or third harmonic distortion compo-
nents. Measurements of MTPR are typically made on the line
side or secondary side of the transformer.
A transformer used at the output of the differential line driver to
step up the differential output voltage to the line has the inverse
effect on signals received from the line. A voltage reduction or
attenuation equal to the inverse of the turns ratio is realized in the
receive channel of a typical bridge hybrid. The turns ratio of the
transformer may also be dictated by the ability of the receive
circuitry to resolve low level signals in the noisy twisted pair tele-
phone plant. While higher turns ratio transformers boost transmit
signals to the appropriate level, they also effectively reduce the
received signal-to-noise ratio due to the reduction in the
received signal strength. Using a transformer with as low a turns
ratio as possible will limit degradation of the received signal.
The AD8022, a dual amplifier with typical RTI voltage noise of
only 2.5 nV/√Hz and a low supply current of 4 mA/amplifier, is
recommended for the receive channel. If power-down is required
for the receive amplifier, two AD8021 low noise amplifiers can
be used instead.
DMT Modulation, Multitone Power Ratio (MTPR), and
Out-of-Band SFDR
4
ADSL systems rely on discrete multitone (DMT) modulation to
carry digital data over phone lines. DMT modulation appears in
the frequency domain as power contained in several individual
frequency subbands, sometimes referred to as tones or bins,
each of which are uniformly separated in frequency. A uniquely
encoded quadrature amplitude modulation (QAM) like signal
occurs at the center frequency of each subband or tone. See
Figure 7 for an example of a DMT waveform in the frequency
domain and Figure 8 for a time domain waveform. Difficulties
will exist when decoding these subbands if a QAM signal from
one subband is corrupted by the QAM signal(s) from other
subband regardless of whether the corruption comes from an
adjacent subband or harmonics of other subbands.
3
2
1
0
–1
–2
–3
–0.25 –0.20 –1.50 –1.00 –0.05
TIME – ms
1.00 1.50 0.20
0.05
0
20
Figure 8. DMT Signal in the Time Domain
TPC 21 and TPC 24 depict MTPR and SFDR versus trans-
former turns respectively for a variety of line power ranging from
12 dBm to 14 dBm. As the turns ratio increases, the driver hybrid
can deliver more undistorted power to the load due to the high
output current capability of the AD8391. Significant degradation
of MTPR will occur if the output transistors of the driver saturate,
causing clipping at the DMT voltage peaks. Driving DMT signals
to such extremes not only compromises in-band MTPR but will
also produce spurs that exist outside of the frequency spectrum
containing the transmitted signal. Out-of-band spurious-free
dynamic range (SFDR) can be defined as the relative difference in
amplitude between these spurs and a tone in one of the upstream
bins. Compromising out-of-band SFDR is the equivalent to
increasing near-end crosstalk (NEXT). Regardless of terminology,
maintaining high out-of-band SFDR while reducing NEXT will
improve the overall performance of the modems connected at either
end of the twisted pair.
0
–20
–40
–60
–80
50
FREQUENCY – kHz
0
100
150
Figure 7. DMT Waveform in the Frequency Domain
REV. A
–13–
AD8391
Generating DMT Signals
Video Driver
At this time, DMT-modulated waveforms are not typically
menu-selectable items contained within arbitrary waveform
generators. Even using AWG software to generate DMT signals,
AWGs that are available today may not deliver DMT signals
sufficient in performance with regard to MTPR due to limitations
in the DACs and output drivers used by AWG manufacturers.
MTPR evaluation requires a DMT signal generator capable of
delivering MTPR performance better than that of the driver under
evaluation. Generating DMT signals can be accomplished using a
Tektronics AWG 2021 equipped with option 4, (12-/24-bit, TTL
digital data out), digitally coupled to Analog Devices’ AD9754, a
14-bit TxDAC, buffered by an AD8002 amplifier configured as
a differential driver. Note that the DMT waveforms, available on
the Analog Devices website (www.analog.com), are similar.
WFM files are needed to produce the necessary digital data
required to drive the TxDAC from the optional TTL digital
data output of the TEK AWG2021.
The AD8391 can be used as a noninverting amplifier by applying a
signal at the VMID pin and grounding the gain resistors (see
Figure 9 for an example circuit). The signal applied to the VMID
pin would be present at both outputs, making this circuit ideal
for any application where one signal needs to be sent to two
different locations, such as a video distribution system. As previ-
ously stated, the AD8391 can operate on split supplies in this
case, eliminating the need for ac-coupling.
The termination resistor should be 76.8 Ω to maintain a 75 Ω
input impedance.
V
EE
10ꢃF
0.1ꢃF
+
909ꢂ
909ꢂ
0.1ꢃF
75ꢂ
75ꢂ
8
1
7
–
+
6
5
V
IN
+V
S
V
MID
AD8391
76.8ꢂ
–V
S
+
–
2
3
4
3V
75ꢂ
909ꢂ
909ꢂ
75ꢂ
0.1ꢃF
10ꢃF
+
V
CC
Figure 9. Driving Two Video Loads from the Same Source
–14–
REV. A
AD8391
Figure 10. Evaluation Board Schematic
REV. A
–15–
AD8391
Figure 11. Layer 1—Primary Side
Figure 12. Silkscreen—Primary Side
–16–
REV. A
AD8391
Figure 13. Layer 2—Ground Plane
Figure 14. Layer 3—Power Plane
REV. A
–17–
AD8391
Figure 15. Layer 4—Secondary Side
Figure 16. Layer 4—Silkscreen
–18–
REV. A
AD8391
Table III. Evaluation Board Bill of Materials
Vendor
Qty.
Description
Ref Des
4
4
14
0.1 µF 50 V 1206 Size Ceramic Chip Capacitor
0 Ω 5% 1/8 W 1206-Size Chip Resistor
DNI
ADS #4-5-18
ADS #3-18-88
C1, C7 to C9
C2, C3, C6, C11
C5, C10, C12 to C17
C22, C25 to C29
C23, C24
IN_NEG, IN_POS
2
4
10 µF 16 V ‘B’-Size Tantalum Chip Capacitor
SMA End Launch Jack (E F JOHNSON #142-0701-801)
ADS #4-7-24
ADS #12-1-31
PWDN, VMID
OUT
J1
L1, L2
PB1
PB3
R1, R23
R2, R33
R17
R18, R21
R19, R20, R22, R24, R35, R38
R25, R26, R30, R31, R39, R40
1
1
2
1
1
2
2
1
2
6
12
DNI
AMP #555154-1 MOD. JACK (SHIELDED) 6 6
FERRITE CORE 1/8 inch BEAD FB43101
DNI
3 Green Terminal Block ONSHORE #EDZ250/3
0 Ω 5% 1/8 W 1206-Size Chip Resistor
DNI
D-K #A 9024
ADS #48-1-1
ADS #12-19-14
ADS #3-18-88
DNI
49.9 Ω Metal Film Resistor
0 Ω Metal Film Resistor
DNI
ADS #3-15-3
ADS #3-2-177
R42, R43, R44, R45, R46, R47
2
2
2
1
2
1
2
2
2
1
1
1
4
4
DNI
R36, R41
R27, R28
R29, R32
T1
TP1, TP4
TP2
TP3, TP5
TP6, TP7
TP8, TP9
Z4
453 Ω Metal Film Resistor
909 Ω Metal Film Resistor
DNI
Red Test Point
Black Test Point
Blue Test Point
Orange Test Point
White Test Point
AD9632 (DNI)
AD8391
AD8138 (DNI)
#4-40 ϫ 1/4 inch Stainless Panhead Machine Screw
#4-40 ϫ 3/4 inch-long Aluminum Round Stand-Off
ADS #3-53-1
ADS #3-53-2
ADS #12-18-43
ADS #12-18-44
ADS #12-18-62
ADS #12-18-60
ADS #12-18-42
ADI #AD9632AR
ADI #AD8391AR
ADI #AD8138AR
ADS #30-1-1
Z5
Z6
ADS #30-16-3
REV. A
–19–
AD8391
OUTLINE DIMENSIONS
8-Lead Standard Small Outline Package [SOIC]
Narrow Body
(R-8)
Dimensions shown in millimeters and (inches)
5.00 (0.1968)
4.80 (0.1890)
8
1
5
4
6.20 (0.2440)
5.80 (0.2284)
4.00 (0.1574)
3.80 (0.1497)
0.50 (0.0196)
0.25 (0.0099)
1.27 (0.0500)
BSC
ꢆ 45ꢄ
1.75 (0.0688)
1.35 (0.0532)
0.25 (0.0098)
0.10 (0.0040)
8ꢄ
0.51 (0.0201)
0.31 (0.0122)
0ꢄ 1.27 (0.0500)
COPLANARITY
0.10
0.25 (0.0098)
0.17 (0.0067)
SEATING
PLANE
0.40 (0.0157)
COMPLIANT TO JEDEC STANDARDS MS-012AA
CONTROLLING DIMENSIONS ARE IN MILLIMETERS; INCH DIMENSIONS
(IN PARENTHESES) ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR
REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN
Revision History
Location
Page
10/03—Data Sheet changed from REV. 0 to REV. A.
Changes to ORDERING GUIDE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Changes to Figure 10. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Updated OUTLINE DIMENSIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
–20–
REV. A
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