AD AD8016AREZ

xDSL line driver that features full ADSL central office (CO)
Performance on ±12 V supplies
Low power operation
±5 V to ±12 V voltage supply
12.5 mA/amp (typical) total supply current
Power reduced keep alive current of 4.5 mA/amp
High output voltage and current drive
IOUT = 600 mA
40 V p-p differential output voltage RL = 50 Ω, VS = ±12 V
Low single-tone distortion
–75 dBc @ 1 MHz SFDR, RL = 100 Ω, VOUT = 2 V p-p
MTPR = –75 dBc, 26 kHz to 1.1 MHz, ZLINE = 100 Ω,
PLINE = 20.4 dBm
High Speed
78 MHz bandwidth (–3 dB), G = +5
40 MHz gain flatness
1000 V/μs slew rate
PIN CONFIGURATIONS
+V1 1
24
VOUT1 2
23
VOUT2
VINN1 3
22
VINN2
VINP1 4
21
VINP2
AGND 5
20
AGND
– +
+ –
AD8016
AGND 6
+V2
AGND
TOP VIEW
(Not to Scale) 18 AGND
17 AGND
AGND 7
AGND 8
19
PWDN0 9
16
PWDN1
DGND 10
15
BIAS
–V1 11
14
–V2
NC 12
13
NC
NC = NO CONNECT
01019-002
FEATURES
Figure 1. 24-Lead SOIC_W_BAT (RB-24)
NC 1
28 NC
NC 2
27 NC
NC 3
26 NC
+VIN2 4
25 NC
–VIN2 5
24 PWDN1
VOUT2 6
23 BIAS
+V2 7
AD8016ARE
22 –V2
+V1 8
TOP VIEW
(Not to Scale)
21 –V1
VOUT1 9
20 DGND
–VIN1 10
19 NC
+VIN1 11
18
PWDN0
NC 12
17 NC
NC 13
16
NC
NC 14
15
NC
NOTES
1. THE EXPOSED PADDLE IS FLOATING,
NOT ELECTRICALLY CONNECTED
INTERNALLY.
2. NC = NO CONNECT.
01019-003
Data Sheet
Low Power, High Output
Current xDSL Line Driver
AD8016
Figure 2. 28-Lead TSSOP_EP (RE-28-1)
GENERAL DESCRIPTION
The AD8016 high output current dual amplifier is designed for
the line drive interface in Digital Subscriber Line systems such
as ADSL, HDSL2, and proprietary xDSL systems. The drivers
are capable, in full-bias operation, of providing 24.4 dBm
output power into low resistance loads, enough to power a
20.4 dBm line, including hybrid insertion loss.
the xDSL hybrid in Figure 35 and Figure 36. Two digital bits
(PWDN0, PWDN1) allow the driver to be capable of full
performance, an output keep-alive state, or two intermediate
bias states. The keep-alive state biases the output transistors
enough to provide a low impedance at the amplifier outputs
for back termination.
The AD8016 is available in a low cost 24-lead SOIC_W_BAT
and a 28-lead TSSOP_EP with an exposed lead frame (ePAD).
Operating from ±12 V supplies, the AD8016 requires only 1.5 W
of total power dissipation (refer to the Power Dissipation section
for details) while driving 20.4 dBm of power downstream using
The low power dissipation, high output current, high output
voltage swing, flexible power-down, and robust thermal
packaging enable the AD8016 to be used as the central office
(CO) terminal driver in ADSL, HDSL2, VDSL, and proprietary
xDSL systems.
Rev. C
Information furnished by Analog Devices is believed to be accurate and reliable. However, no
responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other
rights of third parties that may result from its use. Specifications subject to change without notice. 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.
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www.analog.com
Fax: 781.461.3113
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AD8016
Data Sheet
TABLE OF CONTENTS
Features .............................................................................................. 1
Feedback Resistor Selection ...................................................... 14
Pin Configurations ........................................................................... 1
Bias Pin and PWDN Features ................................................... 14
General Description ......................................................................... 1
Thermal Shutdown .................................................................... 15
Revision History ............................................................................... 2
Applications Information .............................................................. 16
Specifications..................................................................................... 3
Multitone Power Ratio (MTPR) ............................................... 16
Logic Inputs (CMOS Compatible Logic) .................................. 4
Generating DMT ........................................................................ 17
Absolute Maximum Ratings ............................................................ 5
Power Dissipation....................................................................... 17
Maximum Power Dissipation ..................................................... 5
Thermal Enhancements and PCB Layout ............................... 18
ESD Caution .................................................................................. 5
Thermal Testing.......................................................................... 18
Pin Configurations and Function Descriptions ........................... 6
Air Flow Test Conditions .......................................................... 18
Typical Performance Characteristics ............................................. 7
Experimental Results ................................................................. 19
Test Circuts ...................................................................................... 13
Outline Dimensions ....................................................................... 20
Theory of Operation ...................................................................... 14
Ordering Guide .......................................................................... 20
Power Supply and Decoupling .................................................. 14
REVISION HISTORY
3/12—Rev. B to Rev. C
Updated Format .................................................................. Universal
Deleted PSOP Package and Evaluation Boards (Throughout) ... 1
Added Pin Configurations and Function Descriptions Sections .. 7
Updated Outline Dimensions ....................................................... 21
Changes to Ordering Guide .......................................................... 19
11/03—Rev. A to Rev. B
Changes to Ordering Guide ............................................................ 4
Changes to TPC 21 ........................................................................... 8
Updated Outline Dimensions ..................................................19-20
Rev. C | Page 2 of 20
Data Sheet
AD8016
SPECIFICATIONS
@ 25°C, VS = ±12 V, RL = 100 Ω, PWDN0, PWDN1 = (1, 1), TMIN = −40°C, TMAX = +85°C, unless otherwise noted.
Table 1.
Parameter
DYNAMIC PERFORMANCE
−3 dB Bandwidth
Bandwidth for 0.1 dB Flatness
Large Signal Bandwidth
Peaking
Slew Rate
Rise and Fall Time
Settling Time
Input Overdrive Recovery Time
NOISE/DISTORTION PERFORMANCE
Distortion, Single-Ended
Second Harmonic
Third Harmonic
Multitone Power Ratio 1
IMD
IP3
Voltage Noise (RTI)
Input Current Noise
INPUT CHARACTERISTICS
RTI Offset Voltage
+Input Bias Current
–Input Bias Current
Input Resistance
Input Capacitance
Input Common-Mode Voltage Range
Common-Mode Rejection Ratio
OUTPUT CHARACTERISTICS
Output Voltage Swing
Linear Output Current
Short-Circuit Current
Capacitive Load Drive
POWER SUPPLY
Operating Range
Quiescent Current
Recovery Time
Shutdown Current
Power Supply Rejection Ratio
OPERATING TEMPERATURE RANGE
1
Test Conditions/Comments
G = +1, RF = 1.5 kΩ, VOUT = 0.2 V p-p
G = +5, RF = 499 Ω, VOUT < 0.5 V p-p
G = +5, RF = 499 Ω, VOUT = 0.2 V p-p
VOUT = 4 V p-p
VOUT = 0.2 V p-p < 50 MHz
VOUT = 4 V p-p, G = +2
VOUT = 2 V p-p
0.1%, VOUT = 2 V p-p
VOUT = 12.5 V p-p
VOUT = 2 V p-p, G = +5, RF = 499 Ω
fC = 1 MHz, RL = 100 Ω/25 Ω
fC = 1 MHz, RL = 100 Ω/25 Ω
26 kHz to 1.1 MHz, ZLINE = 100 Ω, PLINE = 20.4 dBm
500 kHz, Δf = 10 kHz, RL = 100 Ω/25 Ω
500 kHz, RL = 100 Ω/25 Ω
f = 10 kHz
f = 10 kHz
Min
69
16
−75/−62
−88/−74
−84/−80
42/40
−3.0
−45
−75
−10
58
Single-ended, RL = 100 Ω
G = 5, RL = 10 Ω, f1 = 100 kHz, −60 dBc SFDR
−11
400
Typ
See Figure 48, R20, R21 = 0 Ω, R1 = open.
Rev. C | Page 3 of 20
63
−40
Unit
380
78
38
90
0.1
1000
2
23
350
MHz
MHz
MHz
MHz
dB
V/μs
ns
ns
ns
−77/−64
−93/−76
–75
−88/−85
43/41
2.6
18
dBc
dBc
dBc
dBc
dBm
nV/√Hz
pA√Hz
1.0
4
400
2
4.5
21
+3.0
+45
+75
+10
64
12.5
8
5
4
25
1.5
75
mV
μA
μA
kΩ
pF
V
dB
+11
V
mA
mA
pF
±13
13.2
10
8
6
V
mA/Amp
mA/Amp
mA/Amp
mA/Amp
μs
mA/Amp
dB
°C
600
2000
80
±3
PWDN1, PWDN0 = (1, 1)
PWDN1, PWDN0 = (1, 0)
PWDN1, PWDN0 = (0, 1)
PWDN1, PWDN0 = (0, 0)
To 95% of IQ
250 μA out of bias pin
ΔVS = ±1 V
Max
4.0
+85
AD8016
Data Sheet
@ 25°C, VS = ±6 V, RL = 100 Ω, PWDN0, PWDN1 = (1, 1), TMIN = –40°C, TMAX = +85°C, unless otherwise noted.
Table 2.
Parameter
DYNAMIC PERFORMANCE
–3 dB Bandwidth
Test Conditions/Comments
Bandwidth for 0.1 dB Flatness
Large Signal Bandwidth
Peaking
Slew Rate
Rise and Fall Time
Settling Time
Input Overdrive Recovery Time
NOISE/DISTORTION PERFORMANCE
Distortion, Single-Ended
Second Harmonic
Third Harmonic
Multitone Power Ratio 1
IMD
IP3
Voltage Noise (RTI)
Input Current Noise
INPUT CHARACTERISTICS
RTI Offset Voltage
+Input Bias Current
−Input Bias Current
Input Resistance
Input Capacitance
Input Common-Mode Voltage Range
Common-Mode Rejection Ratio
OUTPUT CHARACTERISTICS
Output Voltage Swing
Linear Output Current
Short-Circuit Current
Capacitive Load Drive
POWER SUPPLY
Quiescent Current
Recovery Time
Shutdown Current
Power Supply Rejection Ratio
OPERATING TEMPERATURE RANGE
Min
G = +1, RF = 1.5 kΩ, VOUT = 0.2 V p-p
G = +5, RF = 499 Ω, VOUT < 0.5 V p-p
G = +5, RF = 499 Ω, VOUT = 0.2 V p-p
VOUT = 1 V rms
VOUT = 0.2 V p-p < 50 MHz
VOUT = 4 V p-p, G = +2
VOUT = 2 V p-p
0.1%, VOUT = 2 V p-p
VOUT = 6.5 V p-p
70
10
G = +5, VOUT = 2 V p-p, RF = 499 Ω
fC = 1 MHz, RL = 100 Ω/25 Ω
fC = 1 MHz, RL = 100 Ω/25 Ω
26 kHz to 138 kHz, ZLINE = 100 Ω, PLINE = 13 dBm
500 kHz, Δf = 110 kHz, RL = 100 Ω/25 Ω
500 kHz
f = 10 kHz
f = 10 kHz
−73/61
−80/−68
−87/−82
42/39
−3.0
−25
−30
−4
60
Single-Ended, RL = 100 Ω
G = +5, RL = 5 Ω, f = 100 kHz, −60 dBc SFDR
−5
300
Typ
320
71
15
80
0.7
300
2
39
350
−75/−63
−82/−70
−68
−88/−83
42/39
4
17
+4
66
RS = 10 Ω
PWDN1, PWDN0 = (1, 1)
PWDN1, PWDN0 = (1, 0)
PWDN1, PWDN0 = (0, 1)
PWDN1, PWDN0 = (0, 0)
To 95% of IQ
250 μA out of bias pin
ΔVS = ±1 V
8
6
4
3
23
1.0
80
PWDN0, PWDN1, VCC = ±12 V or ±6 V; full temperature range.
Table 3.
Typ
Max
VCC
0.8
Rev. C | Page 4 of 20
Unit
V
V
mV
μA
μA
kΩ
pF
V
dB
V
mA
mA
pF
9.7
6.9
5.0
4.1
mA/Amp
mA/Amp
mA/Amp
mA/Amp
μs
mA/Amp
dB
°C
+85
LOGIC INPUTS (CMOS COMPATIBLE LOGIC)
dBc
dBc
dBc
dBc
dBm
nV/√Hz
pA√Hz
+5
2.0
See Figure 48, R20, R21 = 0 Ω, R1 = open.
Min
2.2
0
1.0
MHz
MHz
MHz
MHz
dB
V/μs
ns
ns
ns
+3.0
+25
+30
1
Parameter
Logic 1 Voltage
Logic 0 Voltage
Unit
5
20
0.2
10
10
400
2
420
830
50
63
−40
Max
Data Sheet
AD8016
ABSOLUTE MAXIMUM RATINGS
Storage Temperature Range
Operating Temperature Range
Lead Temperature Range (Soldering 10 sec)
Rating
26.4 V
1.4 W
1.4 W
±VS
±VS
Observe power derating
curves
−65°C to +125°C
−40°C to +85°C
300°C
1
Specification is for device on a 4-layer board with 10 inches2 of 1 oz copper
at 85°C 24-lead SOIC_W_BAT package: θJA = 28°C/W.
2 Specification is for device on a 4-layer board with 9 inches2 of 1 oz copper at
85°C 28-lead (TSSOP_EP) package: θJA = 29°C/W.
Stresses above those listed under Absolute Maximum Ratings
may cause permanent 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.
8
7
6
5
4
SOIC_W_BAT
3
TSSOP-EP
2
1
0
0
10
20
30
40
50
60
AMBIENT TEMPERATURE (°C)
70
80
90
01019-005
Parameter
Supply Voltage
Internal Power Dissipation
SOIC_W_BAT Package1
TSSOP_EP Package2
Input Voltage (Common-Mode)
Differential Input Voltage
Output Short-Circuit Duration
The output stage of the AD8016 is designed for maximum load
current capability. As a result, shorting the output to common
can cause the AD8016 to source or sink 2000 mA. To ensure
proper operation, it is necessary to observe the maximum
power derating curves. Direct connection of the output to
either power supply rail can destroy the device.
MAXIMUM POWER DISSIPATION (W)
Table 4.
Figure 3. Maximum Power Dissipation vs. Temperature for AD8016 for
TJ = 125 °C
ESD CAUTION
MAXIMUM POWER DISSIPATION
The maximum power that can be safely dissipated by the
AD8016 is limited by the associated rise in junction temperature. The maximum safe junction temperature for a plastic
encapsulated 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.
Rev. C | Page 5 of 20
AD8016
Data Sheet
PIN CONFIGURATIONS AND FUNCTION DESCRIPTIONS
NC 1
24
+V2
VOUT1 2
23
VOUT2
VINN1 3
– +
+ –
VINP1 4
21
AGND 5
AGND 7
AGND 8
AD8016
VINN2
VINP2
25 NC
–VIN2 5
24 PWDN1
23 BIAS
+V2 7
AD8016ARE
22 –V2
+V1 8
TOP VIEW
(Not to Scale)
21 –V1
20
AGND
19
AGND
–VIN1 10
19 NC
+VIN1 11
18
16
PWDN1
DGND 10
15
BIAS
–V1 11
14
–V2
NC 12
13
NC
NC = NO CONNECT
+VIN2 4
VOUT1 9
TOP VIEW
(Not to Scale) 18 AGND
17 AGND
PWDN0 9
26 NC
VOUT2 6
20 DGND
PWDN0
NC 12
17 NC
NC 13
16
NC
NC 14
15
NC
NOTES
1. THE EXPOSED PADDLE IS FLOATING,
NOT ELECTRICALLY CONNECTED
INTERNALLY.
2. NC = NO CONNECT.
01019-002
AGND 6
22
27 NC
NC 3
Figure 4. 24-Lead SOIC_W_BAT (RB-24)
01019-003
+V1 1
28 NC
NC 2
Figure 5. 28-Lead TSSOP_EP (RE-28-1)
Table 5. Pin Function Descriptions
SOIC_W_BAT
1
2
3
4
5 to 8, 17 to 20
9
10
11
12, 13
14
15
16
21
22
23
24
Pin No.
TSSOP_EP
8
9
18
20
21
1 to 3, 12 to 17, 19,
25 to 28
22
23
24
6
7
4
5
10
11
EP
Mnemonic
+V1
VOUT1
VINN1
VINP1
AGND
PWDN0
DGND
−V1
NC
Description
Positive Power Supply, Amp 1.
Output Signal, Amp 1.
Negative Input Signal, Amp 1.
Positive Input Signal, Amp1.
Analog Ground.
Power-Down Input 0.
Digital Ground.
Negative Power Supply, Amp1.
This pin is not connected internally (see Figure 4 and Figure 5).
−V2
BIAS
PWDN1
VINP2
VINN2
VOUT2
+V2
+VIN2
−VIN2
−VIN1
+VIN1
EPAD
−V Power Supply, Amp 2.
Quiescent Current Adjust.
Power-Down Input 1.
Positive Input Signal, Amp 2.
Negative Input Signal, Amp 2.
Output Signal, Amp 2.
Positive Power Supply, Amp 2.
Positive Input Signal, Amp 2.
Negative Input Signal, Amp 2.
Negative Input Signal, Amp 1.
Positive Input Signal, Amp 1.
Exposed Pad. The exposed paddle is floating, not electrically connected internally.
Rev. C | Page 6 of 20
Data Sheet
AD8016
TYPICAL PERFORMANCE CHARACTERISTICS
549.3 550.3 551.3 552.3 553.3 554.3 555.3 556.3 557.3 558.3 559.3
FREQUENCY (kHz)
TIME (100ns/DIV)
Figure 6. Multitone Power Ratio; VS = ±12 V, 20.4 dBm Output Power into
100 Ω, Downstream
Figure 9. 100 mV Step Response; G = +5, VS = ±12 V, RL = 25 Ω, Single-Ended
VOLTS
VOUT = 4V
VIN = 20mV
01019-011
VIN = 800mV
01019-008
VOLTS
VOUT = 100mV
TIME (100ns/DIV)
VIN = 20mV
01019-010
VOLTS
–75dBc
01019-004
10dB/DIV
VOUT = 100mV
TIME (100ns/DIV)
Figure 7. 100 mV Step Response; G = +5, VS = ±6 V, RL = 25 Ω, Single-Ended
Figure 10. 4 V Step Response; G = +5, VS = ±12 V, RL = 25 Ω, Single-Ended
–30
RF = 499Ω
G = +10
–40 VOUT = 4V p-p
VOUT = 5V
(0,0)
VOLTS
DISTORTION (dBc)
–50
VIN = 800mV
(0,1)
(1,0)
–60
–70
–80
PWDN1, PWDN0 = (1,1)
–90
–110
0.01
Figure 8. 4 V Step Response; G = +5, VS = ±6 V, RL = 25 Ω, Single-Ended
0.1
1
FREQUENCY (MHz)
10
20
01019-012
01019-009
TIME (100ns/DIV)
–100
Figure 11. Distortion vs. Frequency; Second Harmonic, VS = ±12 V, RL = 50 Ω,
Differential
Rev. C | Page 7 of 20
AD8016
Data Sheet
–30
(0,0)
RF = 499Ω
G = +10
V
–40 OUT = 4V p-p
(0,1)
–50
DISTORTION (dBc)
(1,0)
–60
–70
–80
PWDN1, PWDN0 = (1,1)
–100
10
20
Figure 12. Distortion vs. Frequency; Second Harmonic, VS = ±6 V, RL = 50 Ω
–30
–110
0.01
–30
10
20
RF = 499Ω
G = +5
(1,0)
(0,0)
–45
DISTORTION (dBc)
–50
–55
(0,0)
(0,1)
(1,0)
–60
–65
–70
–50
(0,1)
–60
–70
–80
0
100
300
400
500
600
200
PEAK OUTPUT CURRENT (mA)
700
800
01019-014
PWDN1, PWDN0 = (1,1)
–75
Figure 13. Distortion vs. Peak Output Current; Second Harmonic, VS = ±12 V,
RL = 10 Ω, f = 100 kHz, Single-Ended
–30
–90
0
100
300
400
500
200
PEAK OUTPUT CURRENT (mA)
600
700
Figure 16. Distortion vs. Peak Output Current, Third Harmonic; VS = ±12 V,
RL = 10 Ω, G = +5, f = 100 kHz, Single-Ended
–30
(0,0)
RF = 499Ω
G = +10
–40 VOUT = 4V p-p
PWDN1,
PWDN0 = (1,1)
01019-017
DISTORTION (dBc)
1
FREQUENCY (MHz)
–40
–40
–80
0.1
Figure 15. Distortion vs. Frequency; Third Harmonic, VS = ±6 V, RL = 50 Ω,
Differential
RF = 499Ω
G = +5
–35
PWDN1, PWDN0 = (1,1)
–80
–100
1
FREQUENCY (MHz)
(1,0)
–70
–90
0.1
(0,1)
–60
–90
–110
0.01
(0,0)
–50
01019-013
DISTORTION (dBc)
RF = 499Ω
G = +10
–40 VOUT = 4V p-p
01019-016
–30
RF = 499Ω
G = +5
–35
(0,1)
–40
–60
DISTORTION (dBc)
DISTORTION (dBc)
–50
(1,0)
–70
PWDN1, PWDN0 = (1,1)
–80
–45
(0,0)
–50
(0,1)
–55
(1,0)
–60
–65
–90
–70
0.1
1
FREQUENCY (MHz)
10
20
–80
01019-015
–110
0.01
–75
Figure 14. Distortion vs. Frequency; Third Harmonic, VS = ±12 V, RL = 50 Ω,
Differential
PWDN1, PWDN0 = (1,1)
0
100
200
300
400
PEAK OUTPUT CURRENT (mA)
500
600
01019-018
–100
Figure 17. Distortion vs. Peak Output Current; Second Harmonic, VS = ±6 V,
RL = 5 Ω, f = 100 kHz, Single-Ended
Rev. C | Page 8 of 20
AD8016
–30
–30
–40
–40
–50
–50
DISTORTION (dBc)
(0,0)
–60
(0,1)
–70
(1,0)
(0,0)
(0,1)
–60
(1,0)
–70
–80
–80
PWDN1, PWDN0 = (1,1)
0
5
15
20
25
30
10
DIFFERENTIAL OUTPUT (V p-p)
35
–100
01019-020
–100
PWDN1, PWDN0 = (1,1)
–90
–90
40
0
5
10
15
20
25
30
DIFFERENTIAL OUTPUT (V p-p)
35
01019-023
DISTORTION (dBc)
Data Sheet
40
Figure 21. Distortion vs. Output Voltage; Third Harmonic, VS = ±12 V,
G = +10, f = 1 MHz, RL = 50 Ω, Differential
Figure 18. Distortion vs. Output Voltage; Second Harmonic, VS = ±12 V,
G = +10, f = 1 MHz, RL = 50 Ω, Differential
–30
–30
–40
–40
DISTORTION (dBc)
DISTORTION (dBc)
(0,0)
–50
–60
(0,0)
(0,1)
–70
–50
(0,1)
–60
(1,0)
–70
(1,0)
10
15
5
DIFFERENTIAL OUTPUT (V p-p)
0
20
–90
Figure 19. Distortion vs. Output Voltage; Second Harmonic, VS = ±6 V,
G = +10, f = 1 MHz, RL = 50 Ω, Differential
20
3
–40
–45
–50
(0,0)
–55
(0,1)
–60
(1,0)
–65
–70
–75
0
100
300
400
200
PEAK OUTPUT CURRENT (mA)
500
600
Figure 20. Distortion vs. Peak Output Current; Third Harmonic, VS = ±6 V,
G = +5, RL = 5 Ω, f = 100 kHz, Single-Ended
–3
(1,1)
–6
(1,0)
–9
–12
(0,1)
–15
–18
(0,0)
–21
VIN = 40mV p-p
G = +5
RL = 100Ω
–24
–27
01019-022
PWDN1, PWDN0 = (1,1)
0
1
10
FREQUENCY (MHz)
100
500
01019-025
NORMALIZED FREQUENCY RESPONSE (dB)
–35
DISTORTION (dBc)
5
10
15
DIFFERENTIAL OUTPUT (V p-p)
Figure 22. Distortion vs. Output Voltage, Third Harmonic, VS = ±6 V, G = +10,
f = 1 MHz, RL = 50 Ω, Differential
–30
–80
0
01019-024
PWDN1, PWDN0 = (1,1)
01019-021
–90
PWDN1, PWDN0 = (1,1)
–80
–80
Figure 23. Frequency Response; VS = ±12 V, @ PWDN1, PWDN0 Codes
Rev. C | Page 9 of 20
AD8016
11
Data Sheet
11
G = +5
RL = 100Ω
RF = 499Ω
8
–1
–4
–7
–10
2
–1
–4
–7
–10
–13
–13
–16
–16
1
10
FREQUENCY (MHz)
100
500
–19
10
FREQUENCY (MHz)
1
Figure 24. Output Voltage vs. Frequency; VS = ±12 V
20
10
500
Figure 27. Output Voltage vs. Frequency; VS = ±6 V
–10
VIN = 2V rms
RF = 602Ω
RF = 499Ω
–20
(1,1)
0
100
01019-029
OUTPUT VOLTAGE (dBV)
5
2
01019-026
OUTPUT VOLTAGE (dBV)
5
–19
G = +5
RL = 100Ω
RF = 499Ω
8
(1,0)
–30
+PSRR
–20
–30
PSRR (dB)
CMRR (dB)
–10
(0,1)
–40
–40
–50
–PSRR
–60
(0,0)
–50
–70
–60
100
500
–90
0.01
10
1
FREQUENCY (MHz)
100
500
Figure 28. PSRR vs. Frequency; VS = ±12 V
Figure 25. CMRR vs. Frequency; VS = ±12 V @ PWDN1, PWDN0 Codes
180
90
3
160
80
140
70
120
60
100
50
80
40
+ INPUT CURRENT NOISE (pA/ Hz)
6
0
(1,1)
–3
–6
(1,0)
–9
–12
(0,1)
–15
–18
–21 VIN = 40mV p-p
G = +5
RL = 100Ω
–24
1
(0,0)
60
30
+INOISE
40
20
VIN NOISE
10
20
10
FREQUENCY (MHz)
100
500
01019-028
NORMALIZED FREQUENCY RESPONSE (dB)
0.1
Figure 26. Frequency Response; VS = ±6 V, @ PWDN1, PWDN0 Codes
Rev. C | Page 10 of 20
0
10
INPUT VOLTAGE NOISE (nV/ Hz)
10
1
FREQUENCY (MHz)
100
100k
1k
10k
FREQUENCY (MHz)
Figure 29. Noise vs. Frequency
1M
0
10M
01019-031
0.1
01019-027
–80
0.03
01019-030
–80
–70
G = +2
RF = 1kΩ
VOUT = 2VSTEP
RL = 100Ω
+2mV
(–0.1%)
0
–2mV
(–0.1%)
VOUT
VIN
–5
0
5
10
VOUT – VIN
15
20
25
30
35
40
G = +2
RF = 1kΩ
VOUT = 2VSTEP
RL = 100Ω
+2mV
(–0.1%)
0
–2mV
(–0.1%)
45
TIME (ns)
VIN
VOUT
–5
0
10
5
15
20
25
30
35
40
45
TIME (ns)
Figure 30. Settling Time 0.1%; VS = ±12 V
Figure 33. Settling Time 0.1%; VS = ±6 V
1000
–20
VOUT = 2V p-p
RF = 499Ω
G = +5
–30 R = 100Ω
L
OUTPUT IMPEDANCE (Ω)
100
–40
CROSSTALK (dB)
VOUT – VIN
01019-035
OUTPUT VOLTAGE ERROR (2mV/DIV (0.1%/DIV))
AD8016
01019-032
OUTPUT VOLTAGE ERROR (2mV/DIV (0.1%/DIV))
Data Sheet
–50
–60
–70
(0,0)
(0,1)
10
(1,0)
1
(1,1)
0.1
0.1
1
10
FREQUENCY (MHz)
100
500
0.01
0.03
01019-033
–90
0.03
Figure 31. Output Crosstalk vs. Frequency
0.1
1
10
FREQUENCY (MHz)
100
01019-036
–80
500
Figure 34. Output Impedance vs. Frequency @ PWDN1, PWDN0 Codes
1M
360
100k
320
10k
280
VIN = 2V/DIV
VOUT = 5V/DIV
240
100
200
TRANSIMPEDANCE
10
160
120
1
0.1
80
0.01
40
PHASE (Degrees)
PHASE
1k
0V
VIN
0.001
0.0001
0.001
0.01
0.1
1
10
FREQUENCY (MHz)
100
1k
0
10k
Figure 32. Open-Loop Transimpedance and Phase vs. Frequency
–100
0
100
200
300 400 500
TIME (ns)
600
700
800
900
01019-037
0V
01019-034
TRANSIMPEDANCE (k Ω)
VOUT
Figure 35. Positive Overdrive Recovery; VS = ±12 V, G = +5, RL = 100 Ω
Rev. C | Page 11 of 20
AD8016
Data Sheet
18
VIN = 2V/DIV
VOUT = 5V/DIV
16
PWDN1, PWDN0 = (1,1)
14
0V
VOUT
12
IQ (mA)
(1,0)
0V
10
(0,1)
8
(0,0)
VIN
6
4
100
200
300 400 500
TIME (ns)
600
700
800
900
0
0
50
100
IBIAS (µA)
150
200
01019-040
0
01019-038
2
–100
Figure 38. IQ vs. IBIAS Current; VS = ±6 V
Figure 36. Negative Overdrive Recovery; VS = ±12 V, G = +5, RL = 100 Ω
12
25
+VOUT, VS = ±12V
PWDN1, PWDN0 = (1,1)
8
20
OUTPUT SWING (V)
+VOUT, VS = ±6V
(1,0)
IQ (mA)
15
(0,1)
10
4
0
–4
(0,0)
–VOUT, VS = ±6V
5
–8
50
100
IBIAS (µA)
150
200
Figure 37. IQ vs. IBIAS Current; VS = ±12 V
–12
10
100
1k
RLOAD (Ω)
Figure 39. Output Voltage vs. RLOAD
Rev. C | Page 12 of 20
10k
01019-041
0
01019-039
–VOUT, VS = ±12V
0
Data Sheet
AD8016
TEST CIRCUTS
10µF
+VS
124Ω
499Ω
+
0.1µF
+VIN
VOUT
+VO
49.9Ω
RL
499Ω
111Ω
VIN
49.9Ω
499Ω
RL
+VS
0.1µF
+
10µF
0.1µF
+
10µF
0.1µF
–VIN
–VO
–VS
Figure 40. Single-Ended Test Circuit; G = +5
10µF
+
Figure 41. Differential Test Circuit; G = +10
Rev. C | Page 13 of 20
01019-007
–VS
01019-006
49.9Ω
AD8016
Data Sheet
THEORY OF OPERATION
The AD8016 is a current feedback amplifier with high
(500 mA) output current capability. With a current feedback
amplifier, the current into the inverting input is the feedback
signal and the open-loop behavior is that of a transimpedance,
dVOUT/dIIN or TZ. The open-loop transimpedance is analogous
to the open-loop voltage gain of a voltage feedback amplifier.
Figure 42 shows a simplified model of a current feedback amplifier. Because RIN is proportional to 1/gm, the equivalent voltage
gain is just TZ × gm, where gm is the transconductance of the
input stage. Basic analysis of the follower with gain circuit yields
TZ (S)
VOUT
=G×
TZ (S) + G × RIN + RF
VIN
RIN =
RF
RG
1
≈ 25 Ω
gm
Recognizing that G × RIN << RF for low gains, the familiar result
of constant bandwidth with gain for current feedback amplifiers
is evident, the 3 dB point being set when |TZ| = RF. Of course,
for a real amplifier there are additional poles that contribute
excess phase and there is a value for RF below which the amplifier is unstable. Tolerance for peaking and desired flatness
determines the optimum RF in each application.
RF
RG
–
RIN
IIN
VOUT
+
VIN
In current feedback amplifiers, selection of feedback and gain
resistors has an impact on the MTPR performance, bandwidth,
and gain flatness. Take care in selecting these resistors so that
optimum performance is achieved. Table 6 below shows the
recommended resistor values for use in a variety of gain
settings. These values are suggested as a good starting point
when designing for any application.
Table 6. Resistor Selection Guide
Gain
+1
−1
+2
+5
+10
RF (Ω)
1000
500
650
750
1000
RG (Ω)
∞
500
650
187
111
BIAS PIN AND PWDN FEATURES
01019-042
RN
+
TZ
The AD8016 should be powered with a good quality (that is,
low noise) dual supply of ±12 V for the best distortion and
multitone power ratio (MTPR) performance. Careful attention
must be paid to decoupling the power supply pins. A 10 μF
capacitor located in near proximity to the AD8016 is required
to provide good decoupling for lower frequency signals. In
addition, 0.1 μF decoupling capacitors should be located as
close to each of the four power supply pins as is physically
possible. All ground pins should be connected to a common
low impedance ground plane.
FEEDBACK RESISTOR SELECTION
where:
G =1+
POWER SUPPLY AND DECOUPLING
Figure 42. Simplified Block Diagram
The AD8016 is the first current feedback amplifier capable of
delivering 400 mA of output current while swinging to within
2 V of either power supply rail. This enables full CO ADSL
performance on only 12 V rails, an immediate 20% power
saving. The AD8016 is also unique in that it has a power
management system included on-chip. It features four user
programmable power levels (all of which provide a low output
impedance of the driver), as well as the provision for complete
shutdown (high impedance state). Also featured is a thermal
shutdown with alarm signal.
The AD8016 is designed to cover both central office (CO)
and customer premise equipment (CPE) ends of an xDSL
application. It offers full versatility in setting quiescent bias
levels for the particular application from full on to reduced
bias (in three steps) to full off (via BIAS pin). This versatility
gives the modem designer the flexibility to maximize efficiency
while maintaining reasonable levels of MTPR performance.
Optimizing driver efficiency while delivering the required DMT
power is accomplished with the AD8016 through the use of onchip power management features. Two digitally programmable
logic pins, PWDN1 and PWDN0, may be used to select four
different bias levels: 100%, 60%, 40%, and 25% of full quiescent
power (see Table 7).
Table 7. PWDN Code Selection Guide
PWDN1
Code
1
1
0
0
X
Rev. C | Page 14 of 20
PWDN0
Code
1
0
1
0
X
Quiescent Bias Level
100% (full on)
60%
40%
25% (low ZOUT but not off)
Full off (high ZOUT via 250 μA pulled out of
BIAS pin)
Data Sheet
AD8016
The BIAS control pin by itself is a means to continuously adjust
the AD8016 internal biasing and, thus, quiescent current IQ. By
pulling out a current of 0 μA (or open) to approximately200 μA,
the quiescent current can be adjusted from 100% (full on) to a
full off condition. The full off condition yields a high output
impedance. Because of an on-chip resistor variation of up to
±20%, the actual amount of current required to fully shut down
the AD8016 can vary. To institute a full chip shutdown, a pulldown current of 250 μA is recommended. See Figure 43 for the
logic drive circuit for complete amplifier shutdown. Figure 37
and Figure 38 show the relationship between current pulled out
of the BIAS pin (IBIAS) and the supply current (IQ). A typical
shutdown IQ is less than 1 mA total. Alternatively, an external
pull-down resistor to ground or a current sink attached to the
BIAS pin can be used to set IQ to lower levels (see Figure 44).
The BIAS pin may be used in combination with the PWDN1
and PWDN0 pins; however, diminished MTPR performance
may result when IQ is lowered too much. Current pulled away
from the BIAS pin shunts away a portion of the internal bias
current. Setting PWDN1 or PWDN0 to Logic 0 also shunts
away a portion of the internal bias current. The reduction of
quiescent bias levels due to the use of PWDN1 and PWDN0 is
consistent with the percentages established in Table 7. When
PWDN0 alone is set to Logic 0, and no other means of reducing
the internal bias currents is used, full-rate ADSL signals may be
driven while maintaining reasonable levels of MTPR.
R2
50kΩ
R1*
The AD8016 ARB is designed to incorporate shutdown
protection against accidental thermal overload. In the event
of thermal overload, the AD8016 was designed to shut down
at a junction temperature of 165°C and return to normal
operation at a junction temperature 140°C. The AD8016
continues to operate, cycling on and off, as long as the thermal
overload condition remains. The frequency of the protection
cycle depends on the ambient environment, severity of the
thermal overload condition, the power being dissipated, and
the thermal mass of the PCB beneath the AD8016. When the
AD8016 begins to cycle due to thermal stress, the internal
shutdown circuitry draws current out of the node connected
in common with the BIAS pin, while the voltage at the BIAS
pin goes to the negative rail. When the junction temperature
returns to 140°C, current is no longer drawn from this node,
and the BIAS pin voltage returns to the positive rail. Under
these circumstances, the BIAS pin can be used to trip an alarm
indicating the presence of a thermal overload condition.
Figure 44 also shows three circuits for converting this signal to
a standard logic level.
VCC
V = VCC – 0.2V
10kΩ
BIAS
SHUTDOWN
BIAS
PWDN0
OR
0µA – 200µA
VEE
PWDN1
5V
VCC
10kΩ
5V
BIAS
10kΩ
ALARM
OR
BIAS
1MΩ
100kΩ
1/4 HCF 40109B
SGS–THOMSON
Figure 44. Shutdown and Alarm Circuit
BIAS
2N3904
*R1 = 47kΩ FOR ±12V S OR +12VS,
R1 = 22kΩ FOR ±6VS.
AD8016
200µA
01019-043
3.3V LOGIC
THERMAL SHUTDOWN
Figure 43. Logic Drive of BIAS Pin for Complete Amplifier Shutdown
Rev. C | Page 15 of 20
ALARM
MIN β 350
01019-044
The bias level can be controlled with TTL logic levels (high = 1)
applied to the PWDN1 and PWDN0 pins alone or in combination with the BIAS control pin. The DGND or digital ground
pin is the logic ground reference for the PWDN1 and PWDN0
pins. In typical ADSL applications where ±12 V or ±6 V
supplies (also single supplies) are used, the DGND pin is
connected to analog ground.
AD8016
Data Sheet
APPLICATIONS INFORMATION
ADSL systems rely on discrete multitone 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 is uniformly separated in frequency. (See Figure 6
for an example of downstream DMT signals used in evaluating
MTPR performance.) A uniquely encoded, quadrature amplitude modulation (QAM) signal occurs at the center frequency
of each subband or tone. Difficulties arise when decoding these
subbands if a QAM signal from one subband is corrupted by the
QAM signal(s) from other subbands, regardless of whether the
corruption comes from an adjacent subband or harmonics of
other subbands. Conventional methods of expressing the output
signal integrity of line drivers, such as spurious-free dynamic
range (SFDR), single-tone harmonic distortion or THD, twotone intermodulation distortion (IMD), and third-order intercept (IP3) become significantly less meaningful when amplifiers
are required to drive DMT and other heavily modulated
waveforms. A typical xDSL downstream DMT signal may
contain as many as 256 carriers (subbands or tones) of QAM
signals. MTPR is the relative difference between the measured
power in a typical subband (at one tone or carrier) vs. 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
components.
Z′ ≡
Z2
(2 × N )2
where:
Z' is the primary side impedance as seen by the differential
driver.
Z2 is the line impedance.
N is the transformer turns ratio.
Figure 45 shows the dynamic headroom in each subband of a
downstream DMT waveform vs. turns ratio running at 100%
and 60% of the quiescent power while maintaining −65 dBc
of MTPR at VS = ±12 V.
4
VS = ±12V
PWDN1, PWDN0 = (1,1)
3
VS = ±11.4V
PWDN1, PWDN0 = (1,1)
2
VS = ±12V
PWDN1, PWDN0 = (1,0)
1
0
VS = ±11.4V
PWDN1, PWDN0 = (1,0)
–1
–2
1.0
1.1
1.2
1.3
1.4
1.5
1.6
1.7
DOWNSTREAM TURNS RATIO
1.8
1.9
2.0
Figure 45. Dynamic Headroom vs. XFMR Turns Ratio, VS = ±12 V
Rev. C | Page 16 of 20
01019-045
MULTITONE POWER RATIO (MTPR)
See Figure 6 for a sample of the ADSL downstream spectrum
showing MTPR results while driving 20.4 dBm of power onto
a 100 Ω line. Measurements of MTPR are typically made at
the output (line side) of ADSL hybrid circuits. MTPR can be
affected by the components contained in the hybrid circuit,
including the quality of the capacitor dielectrics, voltage ratings,
and the turns ratio of the selected transformers. Other components aside, an ADSL driver hybrid containing the AD8016 can
be optimized for the best MTPR performance by selecting the
turns ratio of the transformers. The voltage and current demands
from the differential driver changes, depending on the transformer turns ratio. The point on the curve indicating maximum
dynamic headroom is achieved when the differential driver
delivers both the maximum voltage and current while maintaining
the lowest possible distortion. Below this point, the driver has
reserve current-driving capability and experiences voltage
clipping. Above this point, the amplifier runs out of current
drive capability before the maximum voltage drive capability
is reached. Because a transformer reflects the secondary load
impedance back to the primary side by the square of the turns
ratio, varying the turns ratio changes the load across the
differential driver. The following equation may be used to
calculate the load impedance across the output of the differential driver, reflected by the transformers, from the line side of
the xDSL driver hybrid.
DYNAMIC HEADROOM (dB)
The AD8016 dual amplifier forms an integrated single-channel
ADSL line driver. The AD8016 may be applied in driving modulated signals including discrete multitone (DMT) in either
direction; upstream from CPE to the CO and downstream
from CO to CPE. The most significant thermal management
challenge lies in driving downstream information from CO sites
to the CPE. Driving xDSL information downstream suggests
the need to locate many xDSL modems in a single CO site. The
implication is that several modems will be placed onto a single
printed circuit board residing in a card cage located in a variety
of ambient conditions. Environmental conditioners such as fans
or air conditioning may or may not be available, depending on
the density of modems and the facilities contained at the CO
site. To achieve long-term reliability and consistent modem
performance, designers of CO solutions must consider the wide
array of ambient conditions that exist within various CO sites.
Data Sheet
AD8016
Once an optimum turns ratio is determined, the amplifier has
an MTPR performance for each setting of the power-down
pins. Table 8 demonstrates the effects of reducing the total
power dissipated by using the PWDN pins on MTPR performance when driving 20.4 dBm downstream onto the line with
a transformer turns ratio of 1:1.4.
Table 8. Dynamic Power Dissipation of Downstream
Transmission
1
PWDN0
1
0
1
0
PD (W)
1.454
1.262
1.142
0.120
POUT = 23.4 dBm = 220 mW
VOUT @ 50 Ω = 3.31 V rms
VOUT = 2.354 V
at each amplifier output, which yields a PD of 1.81 W.
MTPR
−78 dBc
−75.3 dBc
−57.2 dBc
N/A
Through measurement, a DMT signal of 23.4 dBm requires
1.47 W of power to be dissipated by the AD8016. Figure 46
shows the results of calculation and actual measurements
detailing the relationship between the power dissipated by
the AD8016 vs. the total output power delivered to the back
termination resistors and the load combined. A 1:2 transformer
turns ratio was used in the calculations and measurements.
This mode is quiescent power dissipation.
GENERATING DMT
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 DAC and output drivers used by AWG manufacturers.
Similar to evaluating single-tone distortion performance of an
amplifier, MTPR evaluation requires a DMT signal generator
capable of delivering MTPR performance better than that of
the driver under evaluation.
2.5
2.0
CALCULATED
POWER DISSIPATION
PWDN1
1
1
0
01
The situation is more complicated with a complex modulated
signal. In the case of a DMT signal, taking the equivalent sine
wave power overestimates the power dissipation by ~23%. For
example:
1.5
MEASURED
SINE
MEASURED
DMT
1.0
0.5
To properly size the heat sinking area for the user’s application,
it is important to consider the total power dissipation of the
AD8016. The dc power dissipation for VIN = 0 V is IQ (VCC −
VEE), or 2 × IQ × VS.
For the AD8016 powered on +12 V and −12 V supplies (±VS),
the number is 0.6 W. In a differential driver circuit (Figure 41),
one can use symmetry to simplify the computation for a dc
input signal.
PD = 2 × IQ × VS + 4 × (VS − VOUT )
VOUT
RL
where:
VOUT is the peak output voltage of an amplifier.
This formula is slightly pessimistic due to the fact that some of
the quiescent supply current is commutated during sourcing or
sinking current into the load. For a sine wave source, integration over a half cycle yields
 4V V V 2 
PD = 2 × IQ × VS + 2 OUT S − OUT 
 πR
RL 
L

Rev. C | Page 17 of 20
0
0
100
200
OUTPUT POWER (mW)
300
Figure 46. Power Dissipation vs. Output Power (Including Back
Terminations), See Figure 9 for Test Circuit
01019-046
POWER DISSIPATION
AD8016
Data Sheet
THERMAL ENHANCEMENTS AND PCB LAYOUT
AIR FLOW TEST CONDITIONS
There are several ways to enhance the thermal capacity of the
CO solution. Additional thermal capacity can be created using
enhanced PCB layout techniques such as interlacing (sometimes referred to as stitching or interconnection) of the layers
immediately beneath the line driver. This technique serves to
increase the thermal mass or capacity of the PCB immediately
beneath the driver. The AD8016 in a TSSOP_EP (ARE model)
package can be designed to operate in the CO solution using
prudent measures to manage the power dissipation through
careful PCB design. The ARE package is available for use in
designing the highest density CO solutions. Maximum heat
transfer to the PCB can be accomplished using the ARE
package when the thermal slug is soldered to an exposed
copper pad directly beneath the AD8016. Optimum thermal
performance can be achieved in the ARE package only when
the back of the package is soldered to a PCB designed for
maximum thermal capacity (see Figure 48). Thermal experiments with the ARE package were conducted without soldering
the heat slug to the PCB. Heat transfer was through physical
contact only. The following offers some insight into the AD8016
power dissipation and relative junction temperature, as well as
the effects of PCB size and composition on the junction-to-air
thermal resistance or θJA.
DUT Power
THERMAL TESTING
A wind tunnel study was conducted to determine the relationship between thermal capacity (that is, printed circuit board
copper area), air flow, and junction temperature. Junction-toambient thermal resistance, θJA, was also calculated for the
AD8016 ARE and AD8016 ARB packages. The AD8016 was
operated in a noninverting differential driver configuration,
typical of an xDSL application yet isolated from any other
modem components. Testing was conducted using a 1 oz.
copper board in an ambient temperature of ~24°C over air
flows of 200, 150, 100, and 50 linear feet per minute (LFM)
(0.200 and 400 for AD8016 ARE) and for the ARB packages as
well as in still air. The 4-layer PCB was designed to maximize
the area of copper on the outer two layers of the board, while
the inner layers were used to configure the AD8016 in a
differential driver circuit. The PCB measured 3 inches ×
4 inches in the beginning of the study and was progressively
reduced in size to approximately 2 inches × 2 inches. The
testing was performed in a wind tunnel to control airflow
in units of LFM. The tunnel is approximately 11 inches in
diameter.
A typical DSL DMT signal produces about 1.5 W of power
dissipation in the AD8016 package. The fully biased (PWDN0
and PWDN1 = Logic 1) quiescent current of the AD8016 is
~25 mA. A 1 MHz differential sine wave at an amplitude of
8 V p-p/amplifier into an RLOAD of 100 Ω differential (50 Ω
per side) produces the 1.5 W of power typical in the AD8016
device. (See the Power Dissipation section for details.)
Thermal Resistance
The junction-to-case thermal resistance (θJC) of the AD8016
ARB or SOIC_W_BAT package is 8.6°C/W and for the AD8016
ARE or TSSOP_EP it is 5.6°C/W. These package specifications
were used in this study to determine junction temperature
based on the measured case temperature.
PCB Dimensions of a Differential Driver Circuit
Several components are required to support the AD8016 in a
differential driver circuit. The PCB area necessary for these
components (that is, feedback and gain resistors, ac-coupling
and decoupling capacitors, termination and load resistors)
dictated the area of the smallest PCB in this study, 4.7 square
inches. Further reduction in PCB area, although possible, has
consequences in terms of the maximum operating junction
temperature method of thermal enhancement.) A cooling fan
that draws moving air over the PCB and xDSL drivers, while
not always required, may be useful in reducing the operating
temperature.
Rev. C | Page 18 of 20
Data Sheet
AD8016
35
EXPERIMENTAL RESULTS
ARB 0 LFM
The experimental data suggests that for both packages, and
a PCB as small as 4.7 square inches, reasonable junction
temperatures can be maintained even in the absence of air
flow. The graph in Figure 47 shows junction temperature vs.
airflow for various dimensions of 1 oz. copper PCBs at an
ambient temperature of 24°C in the ARB package. For the
worst-case package, the AD8016 ARB and the worst-case
PCB at 4.7 square inches, the extrapolated junction temperature
for an ambient environment of 85°C would be approximately
132°C with 0 LFM of airflow. If the target maximum junction
temperature of the AD8016 ARB is 125°C, a 4-layer PCB with
1 oz. copper covering the outer layers and measuring 9 square
inches is required with 0 LFM of air flow.
75
+24°C AMBIENT
ARB 4.7 SQ-IN
θJA (°C/W)
ARB 200 LFM
01019-048
7
PCB AREA (SQ-IN)
4
10
50
45
40
35
ARE 0 LFM
30
ARE 200 LFM
25
ARE 400 LFM
20
ARB 9 SQ-IN
10
55
0
1
2
3
4
5
6
PCB AREA (SQ-IN)
7
8
9
10
01019-049
15
ARB 7.125 SQ-IN
60
Figure 49. Junction-to-Ambient Thermal Resistance vs. PCB Area
50
45
0
50
100
AIR FLOW (LFM)
150
200
01019-047
JUNCTION TEMPERATURE (°C)
ARB 150 LFM
20
Figure 48. Junction-to-Ambient Thermal Resistance vs. PCB Area
65
40
25
10
ARB 6 SQ-IN
70
ARB 100 LFM
15
θJA (°C/W)
Note that the AD8016 ARE is targeted at xDSL applications
other than full-rate CO ADSL. The AD8016 ARE is targeted
at g.lite and other xDSL applications where reduced power
dissipation can be achieved through a reduction in output
power. Extreme temperatures associated with full-rate ADSL
using the AD8016 ARE should be avoided whenever possible.
ARB 50 LFM
30
Figure 47. Junction Temperature vs. Air Flow
Rev. C | Page 19 of 20
AD8016
Data Sheet
OUTLINE DIMENSIONS
15.60
15.20
24
13
7.60
7.40
1
10.65
10.00
12
PIN 1
0.75
 45°
0.25
2.65
2.35
0.30
0.10
1.27
BSC
0.51
0.33
SEATING
PLANE
0.32
0.23
8°
0°
1.27
0.40
COMPLIANT WITH JEDEC STANDARDS MS-013-AD
Figure 50. 24-Lead Batwing SOIC, Thermally Enhanced w/Fused Leads [SOIC_W_BAT]
(RB-24)
Dimensions shown in millimeters
9.80
9.70
9.60
3.55
3.50
3.45
15
28
4.50
4.40
4.30
1
14
BOTTOM VIEW
1.05
1.00
0.80
1.20 MAX
SEATING
PLANE
COPLANARITY
0.10
0.65 BSC
0.30
0.19
8°
0°
0.20
0.09
0.75
0.60
0.45
FOR PROPER CONNECTION OF
THE EXPOSED PAD, REFER TO
THE PIN CONFIGURATION AND
FUNCTION DESCRIPTIONS
SECTION OF THIS DATA SHEET.
COMPLIANT TO JEDEC STANDARDS MO-153-AET
02-23-2012-A
TOP VIEW
0.15
0.05
3.05
3.00
2.95
EXPOSED
PAD
(Pins Up)
6.40
BSC
Figure 51. 28-Lead Thin Shrink Small Outline With Exposed Pad [TSSOP_EP]
(RE-28-1)
Dimensions shown in millimeters
ORDERING GUIDE
Model1
AD8016ARBZ
AD8016ARBZ-REEL
AD8016AREZ
AD8016AREZ-REEL
AD8016AREZ-REEL7
1
Temperature Range
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
Package Description
24-Lead SOIC_W_BAT
24-Lead SOIC_W_BAT
28-Lead TSSOP_EP
28-Lead TSSOP_EP
28-Lead TSSOP_EP
Z = RoHS Compliant Part.
©2012 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D01019-0-3/12(C)
Rev. C | Page 20 of 20
Package Option
RB-24
RB-24
RE-28-1
RE-28-1
RE-28-1