NSC CLC452AJ

N
CLC452
Single Supply, Low-Power, High Output,
Current Feedback Amplifier
General Description
Features
The CLC452 has a new output stage that delivers high output
drive current (100mA), but consumes minimal quiescent supply
current (3.0mA) from a single 5V supply. Its current feedback
architecture, fabricated in an advanced complementary bipolar
process, maintains consistent performance over a wide range of
gains and signal levels, and has a linear-phase response up to
one half of the -3dB frequency.
■
■
■
■
■
■
■
■
The CLC452 offers superior dynamic performance with a
130MHz small-signal bandwidth, 400V/µs slew rate and 4.5ns
rise/fall times (2Vstep). The combination of low quiescent power,
high output current drive, and high-speed performance make
the CLC452 well suited for many battery-powered personal
communication/computing systems.
■
100mA output current
3.0mA supply current
130MHz bandwidth (Av = +2)
-78/-85dBc HD2/HD3 (1MHz)
25ns settling to 0.05%
400V/µs slew rate
Stable for capacitive loads up to 1000pF
Single 5V to ±5V supplies
Available in Tiny SOT23-5 package
Applications
■
■
■
■
The ability to drive low-impedance, highly capacitive loads,
makes the CLC452 ideal for single ended cable applications. It
also drives low impedance loads with minimum distortion. The
CLC452 will drive a 100Ω load with only -75/-74dBc second/third
harmonic distortion (Av = +2, Vout = 2Vpp, f = 1MHz). With a 25Ω
load, and the same conditions, it produces only -65/-77dBc second/third harmonic distortion. It is also optimized for driving high
currents into single-ended transformers and coils.
■
■
■
Coaxial cable driver
Twisted pair driver
Transformer/Coil Driver
High capacitive load driver
Video line driver
Portable/battery-powered applications
A/D driver
Maximum Output Voltage vs. RL
10
Output Voltage (Vpp)
9
When driving the input of high-resolution A/D converters, the
CLC452 provides excellent -78/-85dBc second/third harmonic
distortion (Av = +2, Vout = 2Vpp, f = 1MHz, RL = 1kΩ) and fast
settling time.
8
VCC = ±5V
7
6
5
4
3
Vs = +5V
2
1
Available in SOT23-5, the CLC452 is ideal for applications where
space is critical.
+5V
5kΩ
+
7
0.1µF
CLC452
2
-
4
75Ω
6
1kΩ
Response After 10m of Cable
Vin = 10MHz, 0.5Vpp
0.1µF
10m of 75Ω
Coaxial Cable
Vo
100mV/div
5kΩ
3
75Ω
20ns/div
1kΩ
0.1µF
Vo
VCC
Pinout
Pinout
SOT23-5
DIP & SOIC
VEE
Vnon-inv
© 1999 National Semiconductor Corporation
Printed in the U.S.A.
1000
Single Supply Cable Driver
+
0.1µF
100
RL (Ω)
Typical Application
6.8µF
Vin
10
CLC452
Single Supply, Low-Power, High Output, Current Feedback Amp
June 1999
Vinv
VEE
http://www.national.com
+5V Electrical Characteristics (A
v
PARAMETERS
Ambient Temperature
= +2, Rf = 1kΩ, RL = 100Ω, Vs = +5V1, Vcm = VEE + (Vs/2), RL tied to Vcm, unless specified)
CONDITIONS
CLC452AJ
TYP
+25°C
MIN/MAX RATINGS
+25°C
0 to 70°C -40 to 85°C
UNITS
FREQUENCY DOMAIN RESPONSE
-3dB bandwidth
Vo = 0.5Vpp
Vo = 2.0Vpp
-0.1dB bandwidth
Vo = 0.5Vpp
gain peaking
<200MHz, Vo = 0.5Vpp
gain rolloff
<30MHz, Vo = 0.5Vpp
linear phase deviation
<30MHz, Vo = 0.5Vpp
130
95
30
0
0.1
0.1
95
80
25
0.5
0.3
0.2
90
77
20
0.9
0.3
0.3
85
75
20
1.0
0.3
0.3
MHz
MHz
MHz
dB
dB
deg
TIME DOMAIN RESPONSE
rise and fall time
settling time to 0.05%
overshoot
slew rate
4.5
25
11
400
6.0
–
15
300
6.4
–
18
275
6.8
–
18
260
ns
ns
%
V/µs
2V step
1V step
2V step
2V step
DISTORTION AND NOISE RESPONSE
2Vpp, 1MHz
2nd harmonic distortion
2Vpp, 1MHz; RL = 1kΩ
2Vpp, 5MHz
3rd harmonic distortion
2Vpp, 1MHz
2Vpp, 1MHz; RL = 1kΩ
2Vpp, 5MHz
equivalent input noise
voltage (eni)
>1MHz
non-inverting current (ibn)
>1MHz
inverting current (ibi)
>1MHz
-75
-78
-65
-74
-85
-60
-69
-70
-58
-70
-75
-55
-67
-68
-56
-68
-73
-53
-67
-68
-56
-68
-73
-53
dBc
dBc
dBc
dBc
dBc
dBc
2.8
7.5
10.5
3.5
10
14
3.8
11
15
3.8
11
15
nV/√Hz
pA/√Hz
pA/√Hz
STATIC DC PERFORMANCE
input offset voltage
average drift
input bias current (non-inverting)
average drift
input bias current (inverting)
average drift
power supply rejection ratio
common-mode rejection ratio
supply current
1
8
6
40
6
25
48
51
3.0
4
–
18
–
14
–
45
48
3.4
6
–
22
–
16
–
43
46
3.6
6
–
24
–
17
–
43
46
3.6
mV
µV/˚C
µA
nA/˚C
µA
nA/˚C
dB
dB
mA
0.39
1.5
4.2
0.8
4.0
1.0
4.1
0.9
100
70
0.28
2.3
4.1
0.9
3.9
1.1
4.0
1.0
80
105
0.25
2.3
4.0
1.0
3.8
1.2
4.0
1.0
65
105
0.25
2.3
4.0
1.0
3.8
1.2
3.9
1.1
40
140
MΩ
pF
V
V
V
V
V
V
mA
mΩ
DC
DC
RL= ∞
MISCELLANEOUS PERFORMANCE
input resistance (non-inverting)
input capacitance (non-inverting)
input voltage range, High
input voltage range, Low
output voltage range, High
RL = 100Ω
output voltage range, Low
RL = 100Ω
output voltage range, High
RL = ∞
output voltage range, Low
RL = ∞
output current
output resistance, closed loop
DC
NOTES
A
A
A
A
B
Min/max ratings are based on product characterization and simulation. Individual parameters are tested as noted. Outgoing quality levels are
determined from tested parameters.
Absolute Maximum Ratings
Notes
A) J-level: spec is 100% tested at +25°C.
B) The short circuit current can exceed the maximum safe
output current.
1) Vs = VCC - VEE
supply voltage (VCC - VEE)
output current (see note C)
common-mode input voltage
maximum junction temperature
storage temperature range
lead temperature (soldering 10 sec)
ESD rating (human body model)
Reliability Information
Transistor Count
MTBF (based on limited test data)
http://www.national.com
49
31Mhr
2
+14V
140mA
VEE to VCC
+150°C
-65°C to +150°C
+300°C
500V
±5V Electrical Characteristics (A
v
PARAMETERS
Ambient Temperature
= +2, Rf = 1kΩ, RL = 100Ω, VCC = ±5V, unless specified)
CONDITIONS
CLC452AJ
TYP
+25°C
GUARANTEED MIN/MAX
+25°C
0 to 70°C -40 to 85°C
UNITS
FREQUENCY DOMAIN RESPONSE
-3dB bandwidth
Vo = 1.0Vpp
Vo = 4.0Vpp
-0.1dB bandwidth
Vo = 1.0Vpp
gain peaking
<200MHz, Vo = 1.0Vpp
gain rolloff
<30MHz, Vo = 1.0Vpp
linear phase deviation
<30MHz, Vo = 1.0Vpp
differential gain
NTSC, RL=150Ω
differential phase
NTSC, RL=150Ω
160
75
30
0
0.1
0.1
0.05
0.08
135
60
25
0.5
0.2
0.2
–
–
120
57
25
0.9
0.3
0.3
–
–
115
55
20
1.0
0.3
0.3
–
–
MHz
MHz
MHz
dB
dB
deg
%
deg
TIME DOMAIN RESPONSE
rise and fall time
settling time to 0.05%
overshoot
slew rate
3.2
20
8
540
4.2
–
12
400
4.5
–
15
370
5.0
–
15
350
ns
ns
%
V/µs
2V step
2V step
2V step
2V step
DISTORTION AND NOISE RESPONSE
2Vpp, 1MHz
2nd harmonic distortion
2Vpp, 1MHz; RL = 1kΩ
2Vpp, 5MHz
3rd harmonic distortion
2Vpp, 1MHz
2Vpp, 1MHz; RL = 1kΩ
2Vpp, 5MHz
equivalent input noise
voltage (eni)
>1MHz
non-inverting current (ibn)
>1MHz
inverting current (ibi)
>1MHz
-77
-78
-69
-72
-90
-58
-71
-72
-63
-68
-80
-54
-69
-70
-61
-66
-78
-52
-69
-70
-61
-66
-78
-52
dBc
dBc
dBc
dBc
dBc
dBc
2.8
7.5
10.5
3.5
10
14
3.8
11
15
3.8
11
15
nV/√Hz
pA/√Hz
pA/√Hz
STATIC DC PERFORMANCE
input offset voltage
average drift
input bias current (non-inverting)
average drift
input bias current (inverting)
average drift
power supply rejection ratio
common-mode rejection ratio
supply current
1
10
3
40
13
30
48
53
3.2
6
–
18
–
24
–
45
50
3.8
8
–
23
–
31
–
43
48
4.0
8
–
25
–
31
–
43
48
4.0
mV
µV/˚C
µA
nA/˚C
µA
nA/˚C
dB
dB
mA
0.52
1.2
±4.2
±3.8
±4.0
130
60
0.35
1.8
±4.1
±3.6
±3.8
100
90
0.30
1.8
±4.1
±3.6
±3.8
80
90
0.30
1.8
±4.0
±3.5
±3.7
50
120
MΩ
pF
V
V
V
mA
mΩ
DC
DC
RL= ∞
MISCELLANEOUS PERFORMANCE
input resistance (non-inverting)
input capacitance (non-inverting)
common-mode input range
output voltage range
RL = 100Ω
output voltage range
RL = ∞
output current
output resistance, closed loop
DC
Notes
Model
Package Thermal Resistance
Plastic (AJP)
Surface Mount (AJE)
Surface Mount (AJM5)
Dice (ALC)
CerDIP (A8B)
B
Ordering Information
B) The short circuit current can exceed the maximum safe
output current.
Package
NOTES
θJC
θJA
105°C/W
95°C/W
140°C/W
25°C/W
70°C/W
155°C/W
175°C/W
210°C/W
–
215°C/W
3
Temperature Range
CLC452AJP
CLC452AJE
CLC452AJM5
CLC452ALC
CLC452A8B
-40°C
-40°C
-40°C
-40°C
-55°C
CLC452ALC
-55°C to +175°C
to
to
to
to
to
+85°C
+85°C
+85°C
+85°C
+175°C
Description
8-pin PDIP
8-pin SOIC
5-pin SOT
dice
8-pin CerDIP,
MIL-STD-883
dice, MIL-STD-883
http://www.national.com
+5V Typical Performance (A
= +2, Rf = 1kΩ, RL = 100Ω, Vs = +5V1, Vcm = VEE + (Vs/2), RL tied to Vcm, unless specified)
v
Inverting Frequency Response
Phase
0
-90
Av = 5
Rf = 402Ω
-180
-270
Av = 10
Rf = 249Ω
-360
-450
1M
10M
Vo = 0.5Vpp
Av = -1
Rf = 681Ω
Gain
Av = -2
Rf = 604Ω
Phase
-180
-225
-270
Av = -5
Rf = 453Ω
-315
Av = -10
Rf = 402Ω
RL = 1kΩ
10M
Phase
0
-90
RL = 25Ω
-180
-270
-360
-360
-450
100M
1M
10M
Frequency (Hz)
Frequency (Hz)
Frequency Response vs. Vo
RL = 100Ω
Gain
-405
1M
100M
Vo = 0.5Vpp
Magnitude (1dB/div)
Gain
Normalized Magnitude (1dB/div)
Av = 1
Rf = 1kΩ
Phase (deg)
Vo = 0.5Vpp
Frequency Response vs. RL
Phase (deg)
Av = 2
Rf = 750Ω
Phase (deg)
Normalized Magnitude (1dB/div)
Non-Inverting Frequency Response
100M
Frequency (Hz)
Frequency Response vs. CL
Open Loop Transimpedance Gain, Z(s)
120
220
Gain
Vo = 0.5Vpp
Magnitude (1dB/div)
Vo = 0.1Vpp
Magnitude (dBΩ)
Vo = 2.5Vpp
100
CL = 10pF
Rs = 46.4Ω
CL = 100pF
Rs = 20Ω
CL = 1000pF
Rs = 6.7Ω
+
Rs
-
CL
1k
1k
180
Phase
80
140
60
100
40
60
1k
20
1M
10M
1M
100M
10M
Frequency (Hz)
10k
100M
100k
Frequency (Hz)
20
100M
10M
Frequency (Hz)
Equivalent Input Noise
Gain Flatness
1M
2nd & 3rd Harmonic Distortion
12.5
3.2
-40
10
Non-Inverting Current 7.5pA/√Hz
7.5
3
2.9
5
Voltage 2.85nV/√Hz
20
1k
30
100k
1M
3rd
RL = 100Ω
-60
2nd
RL = 1kΩ
-70
2nd
RL = 100Ω
-80
2.5
2.8
10
-50
Distortion (dBc)
Magnitude (0.05dB/div)
3.1
Noise Current (pA/√Hz)
Noise Voltage (nV/√Hz)
Vo = 2Vpp
Inverting Current 10.5pA/√Hz
-90
10M
1M
10M
Frequency (Hz)
Frequency (MHz)
2nd Harmonic Distortion, RL = 25Ω
Frequency (Hz)
3rd Harmonic Distortion, RL = 25Ω
2nd Harmonic Distortion, RL = 100Ω
-60
-35
-44
3rd
RL = 1kΩ
10MHz
-40
-48
5MHz
-50
-52
-54
2MHz
-56
-58
10MHz
-45
5MHz
-50
-55
2MHz
-60
1MHz
-65
1MHz
0.5
1
1.5
2
2.5
0.5
1
1.5
2
2.5
0
-80
10MHz
5MHz
-75
2MHz
Output Amplitude (Vpp)
http://www.national.com
2
2.5
-70
10MHz
-75
-80
5MHz
-85
2MHz
-90
1MHz
-85
1.5
2.5
3rd Harmonic Distortion, RL = 1kΩ
-70
-80
-75
1
2
-60
Distortion (dBc)
Distortion (dBc)
-60
0.5
1.5
-65
5MHz
0
1
-65
10MHz
-55
2MHz
0.5
Output Amplitude (Vpp)
-60
1MHz
-75
2nd Harmonic Distortion, RL = 1kΩ
3rd Harmonic Distortion, RL = 100Ω
-70
2MHz
Output Amplitude (Vpp)
-45
-65
-70
-80
0
Output Amplitude (Vpp)
-50
5MHz
1MHz
-75
0
-65
-70
-60
Distortion (dBc)
Distortion (dBc)
10MHz
Distortion (dBc)
Distortion (dBc)
-46
0
0.5
1MHz
-95
1
1.5
Output Amplitude (Vpp)
4
2
2.5
0
0.5
1
1.5
Output Amplitude (Vpp)
2
2.5
Phase (deg)
Magnitude (1dB/div)
Vo = 1Vpp
+5V Typical Performance (A
= +2, Rf = 1kΩ, RL = 100Ω, Vs = + 5V1, Vcm = VEE + (Vs/2), RL tied to Vcm, unless specified)
v
Closed Loop Output Resistance
Recommended Rs vs. CL
Large & Small Signal Pulse Response
70
+
Rs
CL
1k
50
Rs (Ω)
10
1
1k
1k
40
30
20
0.1
10
0
0.01
100k
1M
10M
10
100M
100
Frequency (Hz)
PSRR & CMRR
IBN, Vos vs. Temperature
Maximum Output Voltage vs. RL
-0.6
60
CMRR
40
30
20
10
0
10k
100k
1M
10M
100M
4.4
-0.7
IBN
4
-0.9
3
-1
2
-1.1
1
-100
2.8
2.4
-50
0
50
100
1.6
150
10
100
Inverting Frequency Response
Av = +1
Rf = 1kΩ
0
-45
-90
Av = +5
Rf = 402
-135
Av = +10
Rf = 249Ω
-180
-225
10M
Normalized Magnitude (1dB/div)
Gain
Vo = 1Vpp
Av = -2
Rf = 604Ω
Gain
Phase
Av = -1
Rf = 681Ω
-225
-270
Av = -5
Rf = 453Ω
-315
Av = -10
Rf = 402Ω
Vo = 1Vpp
RL = 1kΩ
10M
Phase
Vo = 0.1Vpp
-270
-360
-450
1M
100M
10M
Magnitude (1dB/div)
Vo = 2Vpp
Gain Flatness
CL = 10pF
Rs = 68.1Ω
CL = 100pF
Rs = 17.4Ω
CL = 1000pF
Rs = 6.7Ω
+
Rs
-
1k
CL
100M
Frequency (Hz)
Vo = 1Vpp
Vo = 5Vpp
-90
-180
-360
Frequency Response vs. CL
Vo = 1Vpp
0
RL = 25Ω
Frequency (Hz)
Frequency (Hz)
Frequency Response vs. Vo
RL = 100Ω
Gain
-425
1M
100M
-180
Phase (deg)
Av = +2
Rf = 750Ω
Frequency Response vs. RL
Phase (deg)
Vo = 1Vpp
1000
RL (Ω)
= +2, Rf = 1kΩ, RL = 100Ω, VCC = ± 5V, unless specified)
v
Phase (deg)
Normalized Magnitude (1dB/div)
3.2
2
Non-Inverting Frequency Response
Magnitude (1dB/div)
4
3.6
Temperature (°C)
±5V Typical Performance (A
1M
5
Vos
-0.8
Frequency (Hz)
Phase
4.8
Magnitude (0.05dB/div)
1k
6
IBN (µA)
Offset Voltage Vos (mV)
PSRR
50
Time (10ns/div)
1000
CL (pF)
Output Voltage (Vpp)
10k
PSRR & CMRR (dB)
Small Signal
Magnitude (1dB/div)
Output Resistance (Ω)
60
-
Large Signal
Output Voltage (0.5V/div)
100
1k
1k
1M
10M
Frequency (Hz)
100M
1M
10M
100M
Frequency (Hz)
5
0
5
10
15
20
25
30
Frequency (MHz)
http://www.national.com
±5V Typical Performance (A
v
= +2, Rf = 1kΩ, RL = 100Ω, VCC = ± 5V, unless specified)
Small Signal Pulse Response
Large Signal Pulse Response
2nd & 3rd Harmonic Distortion
-40
Output Voltage (1V/div)
Av = -2
-50
Av = +2
Distortion (dBc)
Output Voltage (200mV/div)
Vo = 2Vpp
Av = +2
Av = -2
3rd
RL = 100Ω
-60
2nd
RL = 1kΩ
-70
2nd
RL = 100Ω
-80
3rd
RL = 1kΩ
-90
Time (10ns/div)
Time (10ns/div)
1M
10M
Frequency (Hz)
2nd Harmonic Distortion, RL = 25Ω
3rd Harmonic Distortion, RL = 25Ω
-40
2nd Harmonic Distortion, RL = 100Ω
-30
-55
10MHz
-40
-60
10MHz
5MHz
-55
2MHz
-60
1MHz
10MHz
-50
5MHz
-60
1MHz
-70
2MHz
-80
-65
Distortion (dBc)
-50
Distortion (dBc)
Distortion (dBc)
-45
1
2
3
4
5
-65
2MHz
-70
1MHz
-75
-90
0
5MHz
-80
0
1
Output Amplitude (Vpp)
2
3
4
5
0
1
Output Amplitude (Vpp)
3rd Harmonic Distortion, RL = 100Ω
2nd Harmonic Distortion, RL = 1kΩ
-50
2
3
4
5
Output Amplitude (Vpp)
3rd Harmonic Distortion, RL = 1kΩ
-60
-60
10MHz
-65
10MHz
-60
5MHz
-65
-70
2MHz
-75
1MHz
2MHz
-70
5MHz
-75
10MHz
2
3
4
5
0
Output Amplitude (Vpp)
Recommended Rs vs. CL
1MHz
2
3
4
5
0
Maximum Output Voltage vs. RL
CL
RL
40
30
4
5
Differential Gain & Phase
-0.2
Gain Positive Sync
-0.015
8
-0.3
Gain Negative Sync
6
-0.02
-0.4
-0.025
-0.5
Phase Positive Sync
4
-0.03
-0.6
10
Phase Negative Sync
0
2
10
100
1000
-0.035
10
100
CL (pF)
1000
-0.7
1
2
RL (Ω)
Long Term Settling Time
0.2
12
4
Number of 150Ω Loads
Short Term Settling Time
IBN, Vos vs. Temperature
1.5
3
0.2
Vo = 2Vstep
Vo = 2Vstep
8
4
IBN
Vos
0
0
IBN (µA)
0.5
Vo (% Output Step)
1
Vo (% Output Step)
0.15
0.1
0
-0.1
0.1
0.05
0
-0.05
-0.1
-0.15
-0.5
-4
-100
-50
0
50
Temperature (°C)
http://www.national.com
100
150
-0.2
-0.2
1
10
100
Time (ns)
6
1000
1µ
10µ
100µ
1m
Time (s)
10m
100m
1
Phase (deg)
1k
20
Offset Voltage Vos (mV)
3
-0.01
Gain (%)
1k
2
f = 3.58MHz
Output Voltage (Vpp)
-
1
Output Amplitude (Vpp)
Rs
60
Rs (Ω)
-85
-95
1
10
50
2MHz
-80
Output Amplitude (Vpp)
70
+
5MHz
-75
-90
1MHz
-85
1
-70
-80
-80
0
Distortion (dBc)
-65
Distortion (dBc)
Distortion (dBc)
-55
CLC452 Operation
The CLC452 is a current feedback amplifier built in an
advanced complementary bipolar process. The CLC452
operates from a single 5V supply or dual ±5V supplies.
Operating from a single supply, the CLC452 has the
following features:
■
■
■
Vo
=
Vin
where:
■
Provides 100mA of output current while
consuming 15mW of power
Offers low -78/-85dB 2nd and 3rd harmonic
distortion
Provides BW > 80MHz and 1MHz distortion
< -70dBc at Vo = 2.0Vpp
■
■
■
The CLC452 performance is further enhanced in ±5V
supply applications as indicated in the ±5V Electrical
Characteristics table and ±5V Typical Performance plots.
Av
Rf
1+
Z(jω )
Equation 1
Av is the closed loop DC voltage gain
Rf is the feedback resistor
Z(jω) is the CLC452’s open loop transimpedance
gain
Z( jω )
is the loop gain
Rf
The denominator of Equation 1 is approximately equal to
1 at low frequencies. Near the -3dB corner frequency, the
interaction between Rf and Z(jω) dominates the circuit
performance. The value of the feedback resistor has a
large affect on the circuits performance. Increasing Rf
has the following affects:
Current Feedback Amplifiers
Some of the key features of current feedback technology
are:
■ Independence of AC bandwidth and voltage gain
■ Inherently stable at unity gain
■ Adjustable frequency response with feedback resistor
■ High slew rate
■ Fast settling
■
■
■
■
■
Current feedback operation can be described using a simple
equation. The voltage gain for a non-inverting or inverting
current feedback amplifier is approximated by Equation 1.
Decreases loop gain
Decreases bandwidth
Reduces gain peaking
Lowers pulse response overshoot
Affects frequency response phase linearity
Refer to the Feedback Resistor Selection section for
more details on selecting a feedback resistor value.
CLC452 Design Information
Single Supply Operation (VCC = +5V, VEE = GND)
The specifications given in the +5V Electrical Characteristics table for single supply operation are measured with
a common mode voltage (Vcm) of 2.5V. Vcm is the voltage around which the inputs are applied and the
output voltages are specified.
For single supply DC coupled operation, keep input
signal levels above 0.8V DC. For input signals that drop
below 0.8V DC, AC coupling and level shifting the signal
are recommended. The non-inverting and inverting
configurations for both input conditions are illustrated in
the following 2 sections.
Operating from a single +5V supply, the Common Mode
Input Range (CMIR) of the CLC452 is typically +0.8V to
+4.2V. The typical output range with RL=100Ω is +1.0V
to +4.0V.
DC Coupled Single Supply Operation
Figures 1 and 2 show the recommended non-inverting
and inverting configurations for input signals that remain
above 0.8V DC.
VCC
Note: Rt, RL and Rg are tied
to Vcm for minimum power
consumption and maximum
output swing.
Vin
3
2
Rt
Vcm
Rg
Vcm
Note: Rb, provides DC bias
for non-inverting input.
Rb, RL and Rt are tied
to Vcm for minimum power
consumption and maximum
output swing.
6.8µF
+
+
7
0.1µF
CLC452
-
4
3
Vo
6
Rb
Rf
RL
Vin
Vcm
Rg
2
VCC
6.8µF
+
+
7
0.1µF
CLC452
-
4
Vo
6
Rf
RL
Vcm
Vcm
Rt
R
Vo
= A v = 1+ f
Vin
Rg
Vcm
Figure 1: Non-Inverting Configuration
R
Vo
= Av = − f
Vin
Rg
Select Rt to yield
desired Rin = Rt || Rg
Figure 2: Inverting Configuration
7
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AC Coupled Single Supply Operation
Figures 3 and 4 show possible non-inverting and inverting configurations for input signals that go below 0.8V
DC. The input is AC coupled to prevent the need for
level shifting the input signal at the source. The resistive
voltage divider biases the non-inverting input to VCC ÷ 2
= 2.5V (For VCC = +5V).
VCC
6.8µF
+
Rb
Vin
6.8µF
R
3
VCC
2
2
R
-
4
Rf
1
R
, where: Rin =
2πRinC c
2
R >> R source
6.8µF
+
Vin
Cc
■
3
Rg
2
+
7
0.1µF
CLC452
-
4
6
Vo
■
Rf
 R 
Vo = Vin  − f  + 2.5
 Rg 
1
2πR gC c
VCC
+
Rt
7
0.1µF
CLC452
2
-
4
6
Vo
R
Vo
= A v = 1+ f
Vin
Rg
+
6.8µF
VEE
Figure 5: Dual Supply Non-Inverting Configuration
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Decrease Rf to peak frequency response and
extend bandwidth
Increase Rf to roll off frequency response and
compress bandwidth
Driving Cables and Capacitive Loads
When driving cables, double termination is used to
prevent reflections. For capacitive load applications, a
small series resistor at the output of the CLC452 will
improve stability and settling performance. The
Frequency Response vs. CL and Recommended Rs
vs. CL plots, in the typical performance section, give the
recommended series resistance value for optimum
flatness at various capacitive loads.
Rf
0.1µF
Rg
VEE
Load Termination
The CLC452 can source and sink near equal amounts of
current. For optimum performance, the load should be
tied to Vcm.
6.8µF
+
6.8µF
Bandwidth vs. Output Amplitude
The bandwidth of the CLC452 is at a maximum for
output voltages near 1Vpp. The bandwidth decreases
for smaller and larger output amplitudes. Refer to the
Frequency Response vs. Vo plots.
Dual Supply Operation
The CLC452 operates on dual supplies as well as single
supplies. The non-inverting and inverting configurations
are shown in Figures 5 and 6.
3
0.1µF
Note: Rb provides DC bias
for the non-inverting input.
Select Rt to yield desired
Rin = Rt || Rg.
Unity Gain Operation
The recommended Rf for unity gain (+1V/V) operation
is 1kΩ. Rg is left open. Parasitic capacitance at the
inverting node may require a slight increase in Rf to
maintain a flat frequency response.
Figure 4: AC Coupled Inverting Configuration
Vin
Rf
As a rule of thumb, if the recommended Rf is doubled,
then the bandwidth will be cut in half.
R
low frequency cutoff =
4
Vo
Feedback Resistor Selection
The feedback resistor, Rf, affects the loop gain and
frequency response of a current feedback amplifier.
Optimum performance of the CLC452, at a gain of +2V/V,
is achieved with Rf equal to 1kΩ. The frequency response
plots in the Typical Performance sections
illustrate the recommended Rf for several gains. These
recommended values of Rf provide the maximum bandwidth with minimal peaking. Within limits, Rf can be
adjusted to optimize the frequency response.
VCC
R
-
6
Figure 6: Dual Supply Inverting Configuration
Figure 3: AC Coupled Non-Inverting Configuration
VCC
2
Rg
R
Vo
= Av = − f
Vin
Rg
Vo
6
CLC452
0.1µF
+
0.1µF
Rg
C

R 
Vo = Vin 1 + f  + 2.5
 Rg 
low frequency cutoff =
+
7
7
Rt
+
Cc
+
CLC452
2
VCC
Vin
3
8
1.0
Transmission Line Matching
One method for matching the characteristic impedance
(Zo) of a transmission line or cable is to place the
appropriate resistor at the input or output of the amplifier.
Figure 7 shows typical inverting and non-inverting circuit
configurations for matching transmission lines.
R1
Z0
V1 +-
R3
R2
R4
V2 +-
Z0
Rg
AJP
AJE
Power (W)
0.8
SOT
0.6
0.4
C6
+
Z0
CLC452
-
R6
0.2
Vo
R7
0
Rf
-40 -20
0
20 40 60 80 100 120 140 160 180
Ambient Temperature (°C)
R5
Figure 8: Power Derating Curves
Figure 7: Transmission Line Matching
Layout Considerations
A proper printed circuit layout is essential for achieving
high frequency performance. Comlinear provides
evaluation boards for the CLC452 (730013-DIP, 730027SOIC, 730068-SOT) and suggests their use as a guide
for high frequency layout and as an aid for device testing
and characterization.
Non-inverting gain applications:
■
■
■
Connect Rg directly to ground.
Make R1, R2, R6, and R7 equal to Zo.
Use R3 to isolate the amplifier from reactive
loading caused by the transmission line,
or by parasitics.
General layout and supply bypassing play major roles in
high frequency performance. Follow the steps below as
a basis for high frequency layout:
Inverting gain applications:
■
■
■
Connect R3 directly to ground.
Make the resistors R4, R6, and R7 equal to Zo.
Make R5 II Rg = Zo.
■
■
The input and output matching resistors attenuate the
signal by a factor of 2, therefore additional gain is needed.
Use C6 to match the output transmission line over a
greater frequency range. C6 compensates for the increase
of the amplifier’s output impedance with frequency.
■
■
Power Dissipation
Follow these steps to determine the power consumption
of the CLC452:
■
■
1. Calculate the quiescent (no-load) power:
Pamp = ICC (VCC - VEE)
2. Calculate the RMS power at the output stage:
Po = (VCC - Vload) (Iload), where Vload and Iload
are the RMS voltage and current across the
external load.
3. Calculate the total RMS power:
Pt = Pamp + Po
Include 6.8µF tantalum and 0.1µF ceramic
capacitors on both supplies.
Place the 6.8µF capacitors within 0.75 inches
of the power pins.
Place the 0.1µF capacitors less than 0.1 inches
from the power pins.
Remove the ground plane under and around the
part, especially near the input and output pins to
reduce parasitic capacitance.
Minimize all trace lengths to reduce series
inductances.
Use flush-mount printed circuit board pins for
prototyping, never use high profile DIP sockets.
Evaluation Board Information
Data sheets are available for the CLC730013/
CLC730027 and CLC730068 evaluation boards. The
evaluation board data sheets provide:
■
■
■
The maximum power that the DIP, SOIC, and SOT
packages can dissipate at a given temperature is
illustrated in Figure 8. The power derating curve for
any CLC452 package can be derived by utilizing the
following equation:
Evaluation board schematics
Evaluation board layouts
General information about the boards
The CLC730013/CLC730027 data sheet also contains
tables of recommended components to evaluate several
of Comlinear’s high speed amplifiers. This table for the
CLC452 is illustrated below. Refer to the evaluation
board data sheet for schematics and further information.
(175° − Tamb )
θ JA
Components Needed to Evaluate the
CLC452 on the Evaluation Board:
where
■
Tamb = Ambient temperature (°C)
θJA = Thermal resistance, from junction to ambient,
for a given package (°C/W)
■
9
Rf, Rg - Use this product data sheet to select values
Rin, Rout - Typically 50Ω (Refer to the Basic
Operation section of the evaluation board data
sheet for details)
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■
■
■
Rt - Optional resistor for inverting gain configurations (Select Rt to yield desired input impedance
= Rg || Rt)
C1, C2 - 0.1µF ceramic capacitors
C3, C4 - 6.8µF tantalum capacitors
Gain = K = 1 +
■
■
ωc =
This example illustrates a lowpass filter with Q = 0.707
and corner frequency fc = 10MHz. A Q of 0.707 was chosen to achieve a maximally flat, Butterworth response.
Figure 11 indicates the filter response.
Magnitude (dB)
Application Circuits
Single Supply Cable Driver
The typical application shown on the front page shows
the CLC452 driving 10m of 75Ω coaxial cable. The
CLC452 is set for a gain of +2V/V to compensate for the
divide-by-two voltage drop at Vo.
-15
-18
-21
-24
-30
1M
10M
Figure 11: Lowpass Response
Twisted Pair Driver
The high output current and low distortion, of the
CLC452, make it well suited for driving transformers.
Figure 12 illustrates a typical twisted pair driver utilizing
the CLC452 and a transformer. The transformer
provides the signal and its inversion for the twisted pair.
Vin
3
Rt
0.1µF
2
5kΩ
V = Av Vin
+
CLC452
6
V=
Rm
1:n
3
-
158Ω 158Ω
C2
100pF
2
+
CLC452
-
4
6
0.1µF
UTP
Rf
Req
Rg
Vo
R
A v = 1+ f
Rg
100Ω
IL
RL
C1
7
n
A v Vin
4
Zo
Rf
R2
100M
Frequency (Hz)
+5V
5kΩ
3
0
-3
-6
-9
-12
-27
Single Supply Lowpass Filter
Figures 9 and 10 illustrate a lowpass filter and design
equations. The circuit operates from a single supply of
+5V. The voltage divider biases the non-inverting input to
2.5V. And the input is AC coupled to prevent the need for
level shifting the input signal at the source. Use the
design equations to determine R1, R2, C1, and C2 based
on the desired Q and corner frequency.
R1
1
RC
Figure 10: Design Equations
Support Berkeley SPICE 2G and its many derivatives
Reproduce typical DC, AC, Transient, and Noise
performance
Support room temperature simulations
0.1µF
R1C2
R1C1
+ (1− K)
R 2C1
R 2C 2
1
(3 − K)
Q=
The readme file that accompanies the diskette lists
released models, and provides a list of modeled parameters. The application note OA-18, Simulation SPICE
Models for Comlinear’s Op Amps, contains schematics
and a reproduction of the readme file.
Vin
R 2C 2
+
R1C1
For R1 = R 2 = R and C1 = C2 = C
SPICE Models
SPICE models provide a means to evaluate amplifier
designs. Free SPICE models are available for
Comlinear’s monolithic amplifiers that:
■
1
Q=
C5, C6, C7, C8
R1 thru R8
The evaluation boards are designed to accommodate
dual supplies. The boards can be modified to provide
single supply operation. For best performance; 1) do
not connect the unused supply, 2) ground the unused
supply pin.
■
1
R1R 2C1C2
Corner frequency = ω c =
Components not used:
■
Rf
Rg
V=
-n
A v Vin
4
Vo =
1n
A v Vin
2
Figure 12: Twisted Pair Driver
1kΩ
1.698kΩ Rg
To match the line’s characteristic impedance (Zo) set:
0.1µF
■
■
Figure 9: Lowpass Filter Topology
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10
RL = Zo
Rm = Req
+
Vo
-
Where Req is the transformed value of the load impedance, (RL), and is approximated by:
Req =
The load current (IL) and voltage (Vo) are related to the
CLC452’s maximum output voltage and current by:
RL
Vo ≤ n ⋅ Vmax
n2
IL ≤
Select the transformer so that it loads the line with a
value close to Zo, over the desired frequency range. The
output impedance, Ro, of the CLC452 varies with
frequency and can also affect the return loss. The return
loss, shown below, takes into account an ideal
transformer and the value of Ro.
Return Loss(dB) ≈ − 20log10 n2 ⋅
I max
n
From the above current relationship, it is obvious that an
amplifier with high output drive capability is required.
Ro
Zo
11
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CLC452, Single Supply, Low-Power,
High Output, Current Feedback Amp
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be reasonably expected to result in a significant injury to the user.
2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to
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