LINER 6300I

LT6300
500mA, 200MHz xDSL
Line Driver in 16-Lead SSOP Package
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FEATURES
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DESCRIPTIO
The LT®6300 is a 500mA minimum output current, dual op
amp with outstanding distortion performance. The amplifiers are gain-of-ten stable, but can be easily compensated
for lower gains. The extended output swing allows for
lower supply rails to reduce system power. Supply current
is set with an external resistor to optimize power dissipation. The LT6300 features balanced, high impedance inputs with low input bias current and input offset voltage.
Active termination is easily implemented for further system power reduction. Short-circuit protection and thermal
shutdown insure the device’s ruggedness.
Exceeds All Requirements For Full Rate,
Downstream ADSL Line Drivers
Power Enhanced 16-Lead SSOP Package
Power Saving Adjustable Supply Current
±500mA Minimum IOUT
±10.9V Output Swing, VS = ±12V, RL = 100Ω
±10.7V Output Swing, VS = ±12V, IL = 250mA
Low Distortion: – 82dBc at 1MHz, 2VP-P Into 50Ω
200MHz Gain Bandwidth
600V/µs Slew Rate
Specified at ±12V and ±5V
The outputs drive a 100Ω load to ±10.9V with ±12V
supplies, and ±10.7V with a 250mA load. The LT6300 is a
functional replacement for the LT1739 and LT1794 in
xDSL line driver applications and requires no circuit
changes.
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APPLICATIO S
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High Efficiency ADSL, HDSL2, SHDSL Line Drivers
Buffers
Test Equipment Amplifiers
Cable Drivers
The LT6300 is available in the very small, thermally
enhanced, 16-lead SSOP package (same PCB area as the
SO-8 package) for maximum port density in line driver
applications.
, LTC and LT are registered trademarks of Linear Technology Corporation.
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TYPICAL APPLICATIO
High Efficiency ±12V Supply ADSL Line Driver
12V
24.9k
+
+IN
1/2
LT6300
SHDN
12.7Ω
–
1k
1:2*
•
•
110Ω
100Ω
1000pF
110Ω
1k
–
1/2
LT6300
–IN
+
12.7Ω
*COILCRAFT X8390-A OR EQUIVALENT
ISUPPLY = 10mA PER AMPLIFIER
WITH RSHDN = 24.9k
SHDNREF
6300 TA01
–12V
1
LT6300
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ABSOLUTE MAXIMUM RATINGS
PACKAGE/ORDER INFORMATION
(Note 1)
Supply Voltage (V + to V –) ................................. ±13.5V
Input Current ..................................................... ±10mA
Output Short-Circuit Duration (Note 2) ........... Indefinite
Operating Temperature Range ............... – 40°C to 85°C
Specified Temperature Range (Note 3) .. – 40°C to 85°C
Junction Temperature .......................................... 150°C
Storage Temperature Range ................. – 65°C to 150°C
Lead Temperature (Soldering, 10 sec).................. 300°C
ORDER PART
NUMBER
TOP VIEW
V–
1
V–
16
–IN 2
15 OUT
+IN 3
14 NC
SHDN 4
13 V +
SHDNREF 5
12 V +
+IN 6
11 NC
–IN 7
10 OUT
V– 8
LT6300CGN
LT6300IGN
GN PART
MARKING
V–
9
6300
6300I
GN PACKAGE
16-LEAD PLASTIC SSOP
TJMAX = 150°C, θJA = 70°C/W to 95°C/W (Note 4)
Consult LTC Marketing for parts specified with wider operating temperature
ranges.
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full specified temperature range, otherwise specifications are at TA = 25°C.
VCM = 0V, pulse tested, ±5V ≤ VS ≤ ±12V, VSHDNREF = 0V, RBIAS = 24.9k between V + and SHDN unless otherwise noted. (Note 3)
SYMBOL
PARAMETER
VOS
Input Offset Voltage
CONDITIONS
MIN
TYP
MAX
1
5.0
7.5
mV
mV
0.3
5.0
7.5
mV
mV
●
Input Offset Voltage Matching
●
Input Offset Voltage Drift
IOS
100
500
800
nA
nA
±0.1
±4
±6
µA
µA
100
500
800
nA
nA
●
IB
µV/°C
10
●
Input Offset Current
Input Bias Current
●
Input Bias Current Matching
UNITS
●
en
Input Noise Voltage Density
f = 10kHz
8
nV/√Hz
in
Input Noise Current Density
f = 10kHz
0.8
pA/√Hz
RIN
Input Resistance
VCM = (V + – 2V) to (V –+ 2V)
Differential
50
6.5
MΩ
MΩ
CIN
Input Capacitance
3
pF
CMRR
PSRR
2
Input Voltage Range (Positive)
Input Voltage Range (Negative)
(Note 5)
(Note 5)
Common Mode Rejection Ratio
VCM = (V + – 2V) to (V – + 2V)
Power Supply Rejection Ratio
5
●
●
●
V+
–2
V+
–1
V– + 1
V– + 2
V
V
74
66
83
●
dB
dB
74
66
88
●
dB
dB
VS = ±4V to ±12V
LT6300
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full specified temperature range, otherwise specifications are at TA = 25°C.
VCM = 0V, pulse tested, ±5V ≤ VS ≤ ±12V, VSHDNREF = 0V, RBIAS = 24.9k between V + and SHDN unless otherwise noted. (Note 3)
SYMBOL
PARAMETER
CONDITIONS
AVOL
Large-Signal Voltage Gain
VS = ±12V, VOUT = ±10V, RL = 40Ω
MIN
TYP
63
57
76
●
dB
dB
60
54
70
●
dB
dB
10.7
10.5
10.9
●
±V
±V
10.4
10.2
10.7
●
±V
±V
3.5
3.3
3.8
●
±V
±V
3.4
3.2
3.7
●
±V
±V
500
1200
mA
8.0
6.7
10
VS = ±5V, VOUT = ±3V, RL = 25Ω
VOUT
Output Swing
VS = ±12V, RL = 100Ω
VS = ±12V, IL = 250mA
VS = ±5V, RL = 25Ω
VS = ±5V, IL = 250mA
IOUT
Maximum Output Current
VS = ±12V, RL = 1Ω
IS
Supply Current per Amplifier
VS = ±12V, RBIAS = 24.9k (Note 6)
VS = ±12V, RBIAS = 32.4k (Note 6)
VS = ±12V, RBIAS = 43.2k (Note 6)
VS = ±12V, RBIAS = 66.5k (Note 6)
●
●
2.2
1.8
VSHDN = 0.4V
Output Leakage in Shutdown
VSHDN = 0.4V
Channel Separation
VS = ±12V, VOUT = ±10V, RL = 40Ω
UNITS
13.5
15.0
mA
mA
mA
mA
mA
3.4
5.0
5.8
mA
mA
0.1
1
mA
0.3
1
mA
8
6
4
VS = ±5V, RBIAS = 24.9k (Note 6)
Supply Current in Shutdown
MAX
80
77
110
dB
dB
VS = ±12V, AV = – 10, (Note 7)
300
600
V/µs
VS = ±5V, AV = –10, (Note 7)
100
●
SR
Slew Rate
200
V/µs
HD2
Differential 2nd Harmonic Distortion
VS = ±12V, AV = 10, 2VP-P, RL = 50Ω, 1MHz
– 85
dBc
HD3
Differential 3rd Harmonic Distortion
VS = ±12V, AV = 10, 2VP-P, RL = 50Ω, 1MHz
– 82
dBc
GBW
Gain Bandwidth
f = 1MHz
200
MHz
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
Note 2: Applies to short circuits to ground only. A short circuit between
the output and either supply may permanently damage the part when
operated on supplies greater than ±10V.
Note 3: The LT6300C is guaranteed to meet specified performance from
0°C to 70°C and is designed, characterized and expected to meet these
extended temperature limits, but is not tested at – 40°C and 85°C. The
LT6300I is guaranteed to meet the extended temperature limits.
Note 4: Thermal resistance varies depending upon the amount of PC board
metal attached to Pins 1, 8, 9, 16 of the device. If the maximum
dissipation of the package is exceeded, the device will go into thermal
shutdown and be protected.
Note 5: Guaranteed by the CMRR tests.
Note 6: RBIAS is connected between V + and the SHDN pin, with the
SHDNREF pin grounded.
Note 7: Slew rate is measured at ±5V on a ±10V output signal while
operating on ±12V supplies and ±1V on a ±3V output signal while
operating on ±5V supplies.
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LT6300
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TYPICAL PERFOR A CE CHARACTERISTICS
Supply Current
vs Ambient Temperature
13
12
11
10
9
200
VS = ±12V
180 IS PER AMPLIFIER = 10mA
TA = 25°C
∆VOS > 1mV
–0.5
COMMON MODE RANGE (V)
14
–1.0
160
–1.5
140
–2.0
2.0
40
6
0.5
20
5
–50
V–
–30
–10 10
30
50
TEMPERATURE (°C)
70
90
2
4
8
10
6
SUPPLY VOLTAGE (±V)
12
1
INPUT CURRENT NOISE (pA/√Hz)
10
V+
760
740
720
700
SINKING
680
SOURCING
660
640
620
0.1
10
1
100
1k
FREQUENCY (Hz)
600
–50
0.1
100k
10k
–30
30
–10 10
50
TEMPERATURE (°C)
6300 G04
120
45
100
80
40
–40
20
–80
GAIN
0
–20
–40
–60
–120
–160
TA = 25°C
VS = ±12V
AV = –10
RL = 100Ω
IS PER AMPLIFIER = 10mA
–80
100k
1M
10M
FREQUENCY (Hz)
70
RL = 100Ω
–1.0
ILOAD = 250mA
–1.5
1.5
ILOAD = 250mA
1.0
RL = 100Ω
0.5
V–
– 50 –30
90
–200
100M
6300 G07
50
30
10
TEMPERATURE (°C)
–10
70
Slew Rate vs Supply Current
1000
TA = 25°C
VS = ±12V
AV = 10
RL = 100Ω
35
900
800
30
25
20
15
10
–240
5
–280
0
90
6300 G06
SLEW RATE (V/µs)
40
PHASE (DEG)
0
–3dB BANDWIDTH (MHz)
40
60
90
VS = ±12V
–0.5
–3dB Bandwidth
vs Supply Current
120
80
70
6300 G05
Open-Loop Gain and Phase
vs Frequency
PHASE
10
30
50
–10
TEMPERATURE (°C)
Output Saturation Voltage
vs Ambient Temperature
VS = ±12V
IS PER AMPLIFIER = 10mA
780
in
1
800
100
en
–30
6300 G03
Output Short-Circuit Current
vs Ambient Temperature
TA = 25°C
VS = ±12V
IS PER AMPLIFIER = 10mA
10
0
–50
14
6300 G02
ISC (mA)
100
INPUT VOLTAGE NOISE (V/√Hz)
80
60
Input Noise Spectral Density
GAIN (dB)
100
1.0
6300 G01
4
120
1.5
8
7
OUTPUT SATURATION VOLTAGE (V)
ISUPPLY PER AMPLIFIER (mA)
V+
VS = ±12V
RBIAS = 24.9k TO SHDN
VSHDNREF = 0V
Input Bias Current
vs Ambient Temperature
±IBIAS (nA)
15
Input Common Mode Range
vs Supply Voltage
700
600
TA = 25°C
VS = ±12V
AV = –10
RL = 1k
RISING
FALLING
500
400
300
200
100
2
4
6
8
10
12
14
SUPPLY CURRENT PER AMPLIFIER (mA)
6300 G08
0
2 3 4 5 6 7 8 9 10 11 12 13 14 15
SUPPLY CURRENT PER AMPLIFIER (mA)
6300 G09
LT6300
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TYPICAL PERFOR A CE CHARACTERISTICS
CMRR vs Frequency
100
80
70
60
50
40
30
20
80
0
0.1
1
10
FREQUENCY (MHz)
100
15
60
50
(–) SUPPLY
40
30
(+) SUPPLY
20
–15
–10
0.01
–20
0.1
1
10
FREQUENCY (MHz)
ISHDN (mA)
IS PER
AMPLIFIER = 10mA
IS PER
AMPLIFIER = 15mA
1.5
1.0
0.5
0
100
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0
VSHDN (V)
0
–40
f = 1MHz
TA = 25°C
–50 VS = ±12V
AV = 10
RL = 50Ω
–60 I PER AMPLIFIER = 10mA
S
–45
DISTORTION (dBc)
–50
HD3
–70
–80
HD2
–55
–100
10
20
15
10
5
0
0
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0
VSHDN (V)
12
14
6300 G15
–60
VO = 10VP-P
TA = 25°C
VS = ±12V
AV = 10
RL = 50Ω
IS PER AMPLIFIER = 10mA
–65
–70
–75
–85
8
25
HD3
–80
–90
6
TA = 25°C
VS = ±12V
VSHDNREF = 0V
30
Differential Harmonic Distortion
vs Frequency
–40
4
100M
6300 G12
6300 G14
Differential Harmonic Distortion
vs Output Amplitude
2
100k
1M
10M
FREQUENCY (Hz)
Supply Current vs VSHDN
TA = 25°C
VS = ±12V
VSHDNREF = 0V
6300 G13
DISTORTION (dBc)
OUTPUT IMPEDANCE (Ω)
10
0
10k
35
2.0
IS PER
AMPLIFIER = 2mA
1
10
FREQUENCY (MHz)
1k
100
ISHDN vs VSHDN
100
0.1
15mA PER AMPLIFIER
6300 G11
TA = 25°C
VS ±12V
0.01
0.01
5
–10
2.5
0.1
10mA PER AMPLIFIER
0
0
Output Impedance vs Frequency
1
2mA PER AMPLIFIER
10
–5
10
6300 G10
1000
20
70
10
VS = ±12V
AV = 10
25
SUPPLY CURRENT PER AMPLIFIER (mA)
90
30
VS = ±12V
AV = 10
IS = 10mA PER AMPLIFIER
90
GAIN (dB)
TA = 25°C
VS = ±12V
IS = 10mA PER AMPLIFIER
POWER SUPPLY REJECTION (dB)
COMMON MODE REJECTION RATIO (dB)
100
Frequency Response
vs Supply Current
PSRR vs Frequency
16
18
VOUT(P-P)
6300 G16
HD2
–90
100 200 300 400 500 600 700 800 900 1000
FREQUENCY (kHz)
6300 G17
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LT6300
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TYPICAL PERFOR A CE CHARACTERISTICS
Differential Harmonic Distortion
vs Supply Current
–40
20
–50
OUTPUT VOLTAGE (VP-P)
VO = 10VP-P
VS = ±12V
AV = 10
RL = 50Ω
–45
DISTORTION (dBc)
Undistorted Output Swing
vs Frequency
–55
f = 1MHz, HD3
–60
–65
f = 100kHz, HD2
–70
–75
15
10
5
f = 100kHz, HD3
–80
f = 1MHz, HD2
–85
2
3
4
5
6
7
8
9 10
ISUPPLY PER AMPLIFIER (mA)
SFDR > 40dB
TA = 25°C
VS = ±12V
AV = 10
RL = 50Ω
IS PER AMPLIFIER = 10mA
0
100k
11
300k
1M
3M
FREQUENCY (Hz)
10M
6300 G19
6300 G18
TEST CIRCUIT
SUPPLY BYPASSING
12V
0.1µF
RBIAS
3
12
+
4 (SHDN)
15
–
OUT (+)
110Ω
OUT (–)
110Ω
MINICIRCUITS
ZSC5-2-2
12.7Ω
1:2*
RL ≈ 50Ω
100 LINE LOAD
10k
7
0.01µF
1k
12.7Ω
–
B
6
+
9
8
–12V
6
4.7µF
10
0.1µF
4.7µF
–12V
SPLITTER
49.9Ω
+
VOUT(P-P)
1k
–12V
EIN
0.1µF
16
1
10k
4.7µF
+
13
A
2
12V
+
6300 TC
5 (SHDNREF)
*COILCRAFT X8390-A OR EQUIVALENT
VOUTP-P AMPLITUDE SET AT EACH AMPLIFIER OUTPUT
DISTORTION MEASURED ACROSS LINE LOAD
LT6300
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APPLICATIO S I FOR ATIO
The LT6300 is a high speed, 200MHz gain bandwidth
product, dual voltage feedback amplifier with high output
current drive capability, 500mA source and sink. The
LT6300 is ideal for use as a line driver in xDSL data
communication applications. The output voltage swing
has been optimized to provide sufficient headroom when
operating from ±12V power supplies in full-rate ADSL
applications. The LT6300 also allows for an adjustment of
the operating current to minimize power consumption. In
addition, the LT6300 is available in a small footprint
surface mount package to minimize PCB area.
Setting the Quiescent Operating Current
To minimize signal distortion, the LT6300 amplifiers are
decompensated to provide very high open-loop gain at
high frequency. As a result each amplifier is frequency
stable with a closed-loop gain of 10 or more. If a closedloop gain of less than 10 is desired, external frequency
compensating components can be used.
The internal biasing circuitry is shown in Figure 1. Grounding the SHDNREF pin and directly driving the SHDN pin with
a voltage can control the operating current as seen in the
Typical Performance Characteristics. When the SHDN pin
is less than SHDNREF + 0.4V, the driver is shut down and
consumes typically only 100µA of supply current and the
outputs are in a high impedance state. Part to part variations, however, will cause inconsistent control of the quiescent current if direct voltage drive of the SHDN pin is used.
Power consumption and dissipation are critical concerns
in multiport xDSL applications. Two pins, Shutdown
(SHDN) and Shutdown Reference (SHDNREF), are provided to control quiescent power consumption and allow
for the complete shutdown of the driver. The quiescent
current should be set high enough to prevent distortion
induced errors in a particular application, but not so high
that power is wasted in the driver unnecessarily. A good
starting point to evaluate the LT6300 is to set the quiescent
current to 10mA per amplifier.
SHDN
5I
2k
I
Using a single external resistor, RBIAS, connected in one of
two ways provides a much more predictable control of the
quiescent supply current. Figure 2 illustrates the effect on
supply current per amplifier with RBIAS connected between the SHDN pin and the 12V V + supply of the LT6300
and the approximate design equations. Figure 3 illustrates
the same control with RBIAS connected between the
SHDNREF pin and ground while the SHDN pin is tied to V +.
Either approach is equally effective.
2I
2I
1k
TO
START-UP
CIRCUITRY
IBIAS
TO AMPLIFIERS
BIAS CIRCUITRY
SHDNREF
6300 F01
IBIAS = 2 ISHDN = ISHDNREF
5
ISUPPLY PER AMPLIFIER (mA) = 64 • IBIAS
Figure 1. Internal Current Biasing Circuitry
ISUPPLY PER AMPLIFIER (mA)
30
VS = ±12V
V + = 12V
25
RBIAS
SHDN
20
IS PER AMPLIFIER (mA) ≈
V + – 1.2V • 25.6
RBIAS + 2k
15
RBIAS =
10
V + – 1.2V
• 25.6 – 2k
IS PER AMPLIFIER (mA)
SHDNREF
5
0
7
10
40
70
100
RBIAS (kΩ)
130
160
Figure 2. RBIAS to V+ Current Control
190
6300 F02
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LT6300
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APPLICATIO S I FOR ATIO
45
VS = ±12V
V + = 12V
ISUPPLY PER AMPLIFIER (mA)
40
SHDN
35
V + – 1.2V • 64
IS PER AMPLIFIER (mA) ≈
RBIAS + 5k
30
25
RBIAS =
20
V + – 1.2V
• 64 – 5k
IS PER AMPLIFIER (mA)
SHDNREF
15
RBIAS
10
5
0
4
7
10
30
50
70
90 100 130 150 170 190 210 230 250 270 290
RBIAS (kΩ)
6300 F03
Figure 3. RBIAS to Ground Current Control
12V OR VLOGIC
Two Control Inputs
VC1
H
H
L
L
RESISTOR VALUES (kΩ)
RSHDN TO VCC (12V) RSHDN TO VLOGIC
VLOGIC 3V 3.3V 5V
3V 3.3V 5V
RSHDN 40.2 43.2 60.4 4.99 6.81 19.6
RC1
11.5 13.0 21.5 8.66 10.7 20.5
RCO
19.1 22.1 36.5 14.3 17.8 34.0
VC0
SUPPLY CURRENT PER AMPLIFIER (mA)
H
10
10
10
10
10
10
L
7
7
7
7
7
7
H
5
5
5
5
5
5
L
2
2
2
2
2
2
VLOGIC
VC1
0V
VC0
SHDN
RC0
2k
SHDNREF
One Control Input
12V OR VLOGIC
RESISTOR VALUES (kΩ)
RSHDN TO VCC (12V) RSHDN TO VLOGIC
VLOGIC 3V 3.3V 5V
3V 3.3V 5V
RSHDN 40.2 43.2 60.4 4.99 6.81 19.6
RC
7.32 8.25 13.7 5.49 6.65 12.7
VC
H
L
RSHDN
RC1
VLOGIC
0V
VC
RC
RSHDN
SHDN
2k
SUPPLY CURRENT PER AMPLIFIER (mA)
10
10
10
10
10
10
2
2
2
2
2
2
6300 F04
SHDNREF
Figure 4. Providing Logic Input Control of Operating Current
Logic Controlled Operating Current
The DSP controller in a typical xDSL application can have
I/O pins assigned to provide logic control of the LT6300
line driver operating current. As shown in Figure 4 one or
two logic control inputs can control two or four different
operating modes. The logic inputs add or subtract current
to the SHDN input to set the operating current. The one
logic input example selects the supply current to be either
full power, 10mA per amplifier or just 2mA per amplifier,
which significantly reduces the driver power consumption
8
while maintaining less than 2Ω output impedance to
frequencies less than 1MHz. This low power mode retains
termination impedance at the amplifier outputs and the
line driving back termination resistors. With this termination, while a DSL port is not transmitting data, it can still
sense a received signal from the line across the backtermination resistors and respond accordingly.
The two logic input control provides two intermediate
(approximately 7mA per amplifier and 5mA per amplifier)
operating levels between full power and termination
LT6300
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APPLICATIO S I FOR ATIO
modes. These modes can be useful for overall system
power management when full power transmissions are
not necessary.
Shutdown and Recovery
The ultimate power saving action on a completely idle port
is to fully shut down the line driver by pulling the SHDN pin
to within 0.4V of the SHDNREF potential. As shown in
Figure 5 complete shutdown occurs in less than 10µs and,
more importantly, complete recovery from the shut down
state to full operation occurs in less than 2µs. The biasing
circuitry in the LT6300 reacts very quickly to bring the
amplifiers back to normal operation.
VSHDN
SHDNREF = 0V
AMPLIFIER
OUTPUT
Power Dissipation and Heat Management
xDSL applications require the line driver to dissipate a
significant amount of power and heat compared to other
components in the system. The large peak to RMS variations of DMT and CAP ADSL signals require high supply
voltages to prevent clipping, and the use of a step-up
transformer to couple the signal to the telephone line can
require high peak current levels. These requirements
result in the driver package having to dissipate significant
amounts of power. Several multiport cards inserted into
a rack in an enclosed central office box can add up to
many, many watts of power dissipation in an elevated
ambient temperature environment. The LT6300 has builtin thermal shutdown circuitry that will protect the amplifiers if operated at excessive temperatures, however data
transmissions will be seriously impaired. It is important in
the design of the PCB and card enclosure to take measures
to spread the heat developed in the driver away to the
ambient environment to prevent thermal shutdown (which
occurs when the junction temperature of the LT6300
exceeds 165°C).
Estimating Line Driver Power Dissipation
6300 F05
Figure 6 is a typical ADSL application shown for the
purpose of estimating the power dissipation in the line
driver. Due to the complex nature of the DMT signal,
Figure 5. Shutdown and Recovery Timing
12V
24.9k – SETS IQ PER AMPLIFIER = 10mA
20mA DC
2VRMS
SHDN
17.4Ω
+
+IN
A
–
1k
1:1.7
•
•
110Ω
ILOAD = 57mARMS
1000pF
110Ω
3.16VRMS
1k
–
17.4Ω
6300 F06
B
–IN
100Ω
SHDNREF
+
–12V
–2VRMS
Figure 6. Estimating Line Driver Power Dissipation
9
LT6300
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APPLICATIO S I FOR ATIO
which looks very much like noise, it is easiest to use the
RMS values of voltages and currents for estimating the
driver power dissipation. The voltage and current levels
shown for this example are for a full-rate ADSL signal
driving 20dBm or 100mWRMS of power on to the 100Ω
telephone line and assuming a 0.5dBm insertion loss in
the transformer. The quiescent current for the LT6300 is
set to 10mA per amplifier.
When driving a load, a large percentage of the amplifier
quiescent current is diverted to the output stage and
becomes part of the load current. Figure 7 illustrates the
total amount of biasing current flowing between the + and
– power supplies through the amplifiers as a function of
load current. As much as 60% of the quiescent no load
operating current is diverted to the load.
The power dissipated in the LT6300 is a combination of the
quiescent power and the output stage power when driving
a signal. The two amplifiers are configured to place a
differential signal on to the line. The Class AB output stage
in each amplifier will simultaneously dissipate power in
the upper power transistor of one amplifier, while sourcing current, and the lower power transistor of the other
amplifier, while sinking current. The total device power
dissipation is then:
PD(FULL) = 24V • 8mA + (12V – 2VRMS) • 57mARMS
+ [|–12V – (– 2VRMS)|] • 57mARMS
PD = PQUIESCENT + PQ(UPPER) + PQ(LOWER)
PD = (V+ – V–) • IQ + (V+ – VOUTARMS) •
ILOAD + (V – – VOUTBRMS) • ILOAD
With no signal being placed on the line and the amplifier
biased for 10mA per amplifier supply current, the quiescent driver power dissipation is:
PDQ = 24V • 20mA = 480mW
This can be reduced in many applications by operating
with a lower quiescent current value.
At full power to the line the driver power dissipation is:
PD(FULL) = 192mW + 570mW + 570mW = 1.332W
The junction temperature of the driver must be kept less
than the thermal shutdown temperature when processing
a signal. The junction temperature is determined from the
following expression:
TJ = TAMBIENT (°C) + PD(FULL) (W) • θJA (°C/W)
θJA is the thermal resistance from the junction of the
LT6300 to the ambient air, which can be minimized by
heat-spreading PCB metal and airflow through the enclosure as required. For the example given, assuming a
maximum ambient temperature of 50°C and keeping the
junction temperature of the LT6300 to 150°C maximum,
the maximum thermal resistance from junction to ambient
required is:
θJA(MAX) =
150°C – 50°C
= 75.1°C / W
1.332W
25
TOTAL IQ (mA)
20
15
10
5
0
–240
–200
–160
–120
–80
–40
0
40
ILOAD (mA)
80
120
160
200
240
6300 F07
Figure 7. IQ vs ILOAD
10
LT6300
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Heat Sinking Using PCB Metal
Designing a thermal management system is often a trial
and error process as it is never certain how effective it is
until it is manufactured and evaluated. As a general rule,
the more copper area of a PCB used for spreading heat
away from the driver package, the more the operating
junction temperature of the driver will be reduced. The
limit to this approach however is the need for very compact circuit layout to allow more ports to be implemented
on any given size PCB.
To best extract heat from the GN16 package, a generous
area of top layer PCB metal should be connected to the four
corner pins (Pins 1, 8, 9 and 16). These pins are fused to
the leadframe where the LT6300 die is attached. It is
important to note that this heat spreading metal area is
electrically connected to the V – supply voltage.
Fortunately xDSL circuit boards use multiple layers of
metal for interconnection of components. Areas of metal
beneath the LT6300 connected together through several
small 13 mil vias can be effective in conducting heat away
from the driver package. The use of inner layer metal can
free up top and bottom layer PCB area for external component placement.
When PCB cards containing multiple ports are inserted
into a rack in an enclosed cabinet, it is often necessary to
provide airflow through the cabinet and over the cards.
This is also very effective in reducing the junction-toambient thermal resistance of each line driver. To a limit,
this thermal resistance can be reduced approximately
5°C/W for every 100lfpm of laminar airflow.
the input capacitance to form a pole that can cause
frequency peaking. In general, use feedback resistors of
1k or less.
Compensation
The LT6300 is stable in a gain 10 or higher for any supply
and resistive load. It is easily compensated for lower gains
with a single resistor or a resistor plus a capacitor.
Figure␣ 8 shows that for inverting gains, a resistor from the
inverting node to AC ground guarantees stability if the
parallel combination of RC and RG is less than or equal to
RF/9. For lowest distortion and DC output offset, a series
capacitor, CC, can be used to reduce the noise gain at
lower frequencies. The break frequency produced by RC
and CC should be less than 5MHz to minimize peaking.
Figure 9 shows compensation in the noninverting configuration. The RC, CC network acts similarly to the inverting
case. The input impedance is not reduced because the
network is bootstrapped. This network can also be placed
between the inverting input and an AC ground.
RF
RG
RC
CC
(OPTIONAL)
The parallel combination of the feedback resistor and gain
setting resistor on the inverting input can combine with
VO
+
(RC || RG) ≤ RF/9
1
< 5MHz
2πRCCC
6300 F08
Figure 8. Compensation for Inverting Gains
Layout and Passive Components
With a gain bandwidth product of 200MHz the LT6300
requires attention to detail in order to extract maximum
performance. Use a ground plane, short lead lengths and
a combination of RF-quality supply bypass capacitors (i.e.,
0.1µF). As the primary applications have high drive current, use low ESR supply bypass capacitors (1µF to 10µF).
VO –RF
=
RG
VI
–
VI
RF
VO
=1+
VI
RG
+
VI
RC
CC
(OPTIONAL)
VO
–
RF
(RC || RG) ≤ RF/9
1
< 5MHz
2πRCCC
RG
6300 F09
Figure 9. Compensation for Noninverting Gains
11
LT6300
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Another compensation scheme for noninverting circuits is
shown in Figure 10. The circuit is unity gain at low frequency and a gain of 1 + RF/RG at high frequency. The DC
output offset is reduced by a factor of ten. The techniques
of Figures 9 and 10 can be combined as shown in Figure␣ 11. The gain is unity at low frequencies, 1 + RF/RG at
mid-band and for stability, a gain of 10 or greater at high
frequencies.
In differential driver applications, as shown on the first
page of this data sheet, it is recommended that the gain
setting resistor be comprised of two equal value resistors
connected to a good AC ground at high frequencies. This
ensures that the feedback factor of each amplifier remains
less than 0.1 at any frequency. The midpoint of the
resistors can be directly connected to ground, with the
resulting DC gain to the VOS of the amplifiers, or just
bypassed to ground with a 1000pF or larger capacitor.
A back-termination resistor also equal to the chararacteristic
impedance should be used for maximum pulse fidelity of
outgoing signals, and to terminate the line for incoming
signals in a full-duplex application. There are three main
drawbacks to this approach. First, the power dissipated in
the load and back-termination resistors is equal so half of
the power delivered by the amplifier is wasted in the
termination resistor. Second, the signal is halved so the
gain of the amplifer must be doubled to have the same
overall gain to the load. The increase in gain increases
noise and decreases bandwidth (which can also increase
distortion). Third, the output swing of the amplifier is
doubled which can limit the power it can deliver to the load
for a given power supply voltage.
An alternate method of back-termination is shown in
Figure 13. Positive feedback increases the effective backtermination resistance so RBT can be reduced by a factor
Line Driving Back-Termination
The standard method of cable or line back-termination is
shown in Figure 12. The cable/line is terminated in its
characteristic impedance (50Ω, 75Ω, 100Ω, 135Ω, etc.).
VI
CABLE OR LINE WITH
CHARACTERISTIC IMPEDANCE RL
+
RBT
VO
–
RL
RF
6300 F12
RBT = RL
+
Vi
VO
–
Figure 12. Standard Cable/Line Back Termination
RG ≤ RF/9
RF
VO 1
= (1 + RF/RG)
VI 2
RG
VO
= 1 (LOW FREQUENCIES)
VI
R
= 1 + F (HIGH FREQUENCIES)
RG
1
< 5MHz
2πRGCC
RG
RP2
RP1
CC
VI
+
VA RBT
VP
6300 F10
–
Figure 10. Alternate Noninverting Compensation
VO
RL
RF
+
VI
RC
RG
1+
CC
RF
RG
CBIG
VO
= 1 AT LOW FREQUENCIES
VI
R
= 1 + F AT MEDIUM FREQUENCIES
RG
=1+
RF
AT HIGH FREQUENCIES
(RC || RG)
6300 F11
Figure 11. Combination Compensation
12
FOR RBT =
( )(
VO
–
6300 F13
RL
n
)
1
RP1
RF
=1–
n
RG RP1 + RP2
RP2/(RP2 + RP1)
VO
=
VI
1 + 1/n
( )
R
1+ F
RG
–
RP1
RP2 + RP1
Figure 13. Back Termination Using Postive Feedback
LT6300
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of n. To analyze this circuit, first ground the input. As RBT␣ =
RL/n, and assuming RP2>>RL we require that:
VA = VO (1 – 1/n) to increase the effective value of
RBT by n.
VP = VO (1 – 1/n)/(1 + RF/RG)
RF/RP = 1 – 1/n
So to reduce the back-termination by a factor of 3 choose
RF/RP = 2/3. Note that the overall gain is increased to:
VO/VI = (1 + RF/RG + RF/RP)/[2(1 – RF/RP)]
VO = VP (1 + RP2/RP1)
Using positive feedback is often referred to as active
termination.
Eliminating VP, we get the following:
(1 + RP2/RP1) = (1 + RF/RG)/(1 – 1/n)
For example, reducing RBT by a factor of n = 4, and with an
amplifer gain of (1 + RF/RG) = 10 requires that RP2/RP1
=␣ 12.3.
Note that the overall gain is increased:
RP2 / (RP2 + RP1)
VO
=
VI
(1+ 1/n) / (1+ RF /RG ) − RP1/(RP2 + RP1)
[
solving
] [
]
A simpler method of using positive feedback to reduce the
back-termination is shown in Figure 14. In this case, the
drivers are driven differentially and provide complementary outputs. Grounding the inputs, we see there is inverting gain of –RF/RP from –VO to VA
VA = VO (RF/RP)
and assuming RP >> RL, we require
VA = VO (1 – 1/n)
Figure 16 shows a full-rate ADSL line driver incorporating
positive feedback to reduce the power lost in the back
termination resistors by 40% yet still maintains the proper
impedance match to the100Ω characteristic line impedance. This circuit also reduces the transformer turns ratio
over the standard line driving approach resulting in lower
peak current requirements. With lower current and less
power loss in the back termination resistors, this driver
dissipates only 1W of power, a 30% reduction.
While the power savings of positive feedback are attractive
there is one important system consideration to be addressed, received signal sensitivity. The signal received
from the line is sensed across the back termination resistors. With positive feedback, signals are present on both
ends of the RBT resistors, reducing the sensed amplitude.
Extra gain may be required in the receive channel to
compensate, or a completely separate receive path may be
implemented through a separate line coupling transformer.
Considerations for Fault Protection
+
VI
VA RBT
VO
–
FOR RBT =
RF
n=
RG
RP
RP
VO
=
VI
RL
RF
1
RF
RP
1–
RL
RG
RL
n
R R
1+ F + F
RG RP
( )
2 1–
–
RF
RP
RBT
–VI
+
–VA
–VO
6300 F14
Figure 14. Back Termination Using Differential Postive Feedback
The basic line driver design, shown on the front page of
this data sheet, presents a direct DC path between the
outputs of the two amplifiers. An imbalance in the DC
biasing potentials at the noninverting inputs through
either a fault condition or during turn-on of the system can
create a DC voltage differential between the two amplifier
outputs. This condition can force a considerable amount
of current to flow as it is limited only by the small valued
back-termination resistors and the DC resistance of the
transformer primary. This high current can possibly cause
the power supply voltage source to drop significantly
impacting overall system performance. If left unchecked,
the high DC current can heat the LT6300 to thermal
shutdown.
13
LT6300
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Using DC blocking capacitors, as shown in Figure 15, to
AC couple the signal to the transformer eliminates the
possibility for DC current to flow under any conditions.
These capacitors should be sized large enough to not
impair the frequency response characteristics required for
the data transmission.
Another important fault related concern has to do with
very fast high voltage transients appearing on the telephone line (lightning strikes for example). TransZorbs®,
varistors and other transient protection devices are often
used to absorb the transient energy, but in doing so also
create fast voltage transitions themselves that can be
coupled through the transformer to the outputs of the line
driver. Several hundred volt transient signals can appear
at the primary windings of the transformer with current
into the driver outputs limited only by the back termination
resistors. While the LT6300 has clamps to the supply rails
at the output pins, they may not be large enough to handle
the significant transient energy. External clamping diodes,
such as BAV99s, at each end of the transformer primary
help to shunt this destructive transient energy away from
the amplifier outputs.
TransZorb is a registered trademark of General Instruments, GSI
12V
12V –12V
24.9k
+
+IN
BAV99
0.1µF
1/2
LT6300
SHDN
12.7Ω
–
1k
1:2
•
•
110Ω
LINE
LOAD
1000pF
110Ω
1k
–
0.1µF
1/2
LT6300
–IN
+
–12V
12.7Ω
SHDNREF
BAV99
12V –12V
6300 F15
Figure 15. Protecting the Driver Against Load Faults and Line Transients
14
LT6300
W
W
SI PLIFIED SCHE ATIC
(one amplifier shown)
V+
Q9
Q10
Q13
Q17
Q3
–IN
Q7
C1
R1
Q1
Q6
Q2
Q5
C2
Q4
Q14
+IN
OUT
Q15
Q8
Q18
Q16
Q12
Q11
V–
6300 SS
U
PACKAGE DESCRIPTIO
GN Package
16-Lead Plastic SSOP (Narrow .150 Inch)
(Reference LTC DWG # 05-08-1641)
0.189 – 0.196*
(4.801 – 4.978)
16 15 14 13 12 11 10 9
0.229 – 0.244
(5.817 – 6.198)
0.150 – 0.157**
(3.810 – 3.988)
1
0.015 ± 0.004
× 45°
(0.38 ± 0.10)
0.007 – 0.0098
(0.178 – 0.249)
0.009
(0.229)
REF
2 3
4
5 6
7
0.053 – 0.068
(1.351 – 1.727)
8
0.004 – 0.0098
(0.102 – 0.249)
0° – 8° TYP
0.016 – 0.050
(0.406 – 1.270)
0.008 – 0.012
(0.203 – 0.305)
0.0250
(0.635)
BSC
* DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
** DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
GN16 (SSOP) 1098
15
LT6300
U
TYPICAL APPLICATIO
12V
24.9k
+
+IN
SHDN
1/2
LT6300
13.7Ω
–
1k
1:1.2*
1.65k
•
•
182Ω
100Ω
LINE
1.65k
1000pF
182Ω
1k
–
1/2
LT6300
+
–IN
13.7Ω
*COILCRAFT X8502-A OR EQUIVALENT
1W DRIVER POWER DISSIPATION
1.15W POWER CONSUMPTION
SHDNREF
6300 F16
–12V
Figure 16. ADSL Line Driver Using Active Termination
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LT1361
Dual 50MHz, 800V/µs Op Amp
±15V Operation, 1mV VOS, 1µA IB
LT1739
Dual 500mA, 200MHz xDSL Line Driver
Low Cost ADSL CO Driver, Low Power
LT1794
Dual 500mA, 200MHz xDSL Line Driver
ADSL CO Driver, Extended Output Swing, Low Power
LT1795
Dual 500mA, 50MHz Current Feedback Amplifier
Shutdown/Current Set Function, ADSL CO Driver
LT1813
Dual 100MHz, 750V/µs, 8nV/√Hz Op Amp
Low Noise, Low Power Differential Receiver, 4mA/Amplifier
LT1886
Dual 200mA, 700MHz Op Amp
12V Operation, 7mA/Amplifier, ADSL Modem Line Driver
LT1969
Dual 200mA, 700MHz Op Amp with Power Control
12V Operation, MSOP Package, ADSL Modem Line Driver
16
Linear Technology Corporation
6300f LT/TP 0701 2K • PRINTED IN THE USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
 LINEAR TECHNOLOGY CORPORATION 2001