NSC CLC503

N
Comlinear CLC503
180MHz, Differential-Output Amplifier
General Description
Features
The Comlinear CLC503 is a single-ended to differential amplifier.
It utilizes a pair of closed-loop transconductance amplifiers to
provide wideband, high fidelity, differential output signals. Internal
resistors set the differential gain to 2V/V. With a ground-centered
2Vpp input signal, the CLC503 will produce a 4Vpp differential
output signal. This differential output signal is centered around an
adjustable common mode voltage. An independent input controls
the common mode output voltage. The CLC503 has harmonic
distortion products of -77dBc or less, and a signal to noise ratio of
72dB. The output stage is optimized for loads with signal ranges
between +0.7 and +3.9 volts, such as those found on single
supply CMOS ADCs. Overdrive recovery time of the CLC503
and following circuitry is optimized by the output limiting of the
CLC503. The power down pin (PDN) allows for power savings
in applications where unused circuitry is placed in a low
power mode.
■
■
■
■
-77dBc distortion (10MHz, 4Vpp)
72dB SNR (4Vpp)
15ns settling (0.1%)
180MHz bandwidth
Applications
■
■
Single-to-differential conversion
Single supply ADC signal conditioner
Harmonic Distortion vs. Amplitude
-60
Comlinear CLC503
180MHz, Differential-Output Amplifier
August 1996
RL = 2kΩ
Distortion (dBc)
-65
The CLC503 is an ideal amplifier to drive the differential inputs
of the Comlinear CLC949, 12-bit, 20MSPS, analog-to-digital
converter. It is tailored for driving single supply, differential
input, analog-to-digital converters which require fast settling, high
fidelity inputs.
-70
10MHz
5MHz
-75
-80
1MHz
-85
2MHz
-90
0
1
2
3
4
5
Output Amplitude (Vpp)
Typical Application Diagram
Pinout
SOIC
ADC Clock
PDN
74AC04
Power Down
Vin
CLC503
Vin
VREFMO
0.1µF
PDN
Vcm
Vin
+Vo
VINP
GND
-Vo
VINN
VEE
VCC
CLK
AMP
2K CORE
+Vo
GND
-Vo
VEE
VCC
CLC949
12b/20MSPS ADC
0.1µF
6.8µF
0.1µF
6.8µF
BIASC
Vcm
2K
VCC
GND
0.1µF
-5V
© 1996 National Semiconductor Corporation
Printed in the U.S.A.
+5V
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Electrical Characteristics (VCC = + 5V, VEE = - 5V, Vcm = 2.25V, CL = 5pF, Vo = 4Vpp unless specified)
PARAMETERS
Ambient Temperature
CONDITIONS
CLC503
TYP
+25˚C
FREQUENCY DOMAIN RESPONSE
Differential Amp
large signal bandwidth
gain flatness
Common-Mode Amp
-3dB bandwidth
Vo < 4.0Vpp
DC to 10MHz
180
0.3
80
0.5
70
0.5
MHz
dB
Vo < 4.0Vpp
15
10
10
MHz
TIME DOMAIN RESPONSE
Differential Amp
rise and fall time
settling time to 0.1%
overshoot
slew rate
Common-Mode Amp
recovery from power down
2V step
2V step
2V step
2V step
2.1
15
0
800
2.5
22
3.0
25
500
500
ns
ns
%
V/µs
0.1% output settling
40
100
100
ns
4Vpp, 1MHz
4Vpp, 10MHz
4Vpp, 1MHz
4Vpp, 10MHz
4Vpp
Rs = 50Ω
10kHz – 500MHz
-78
-75
-85
-77
72
-74
-71
-80
-72
71
-70
-71
-79
-72
70
dBc
dBc
dBc
dBc
dB
325
380
460
µVrms
Vo(Diff)/Vin
Vin = 0
2
10
0.015
2
1.75 - 2.25
90
0.03
1.6 - 2.4
1.75 - 2.25
100
0.05
1.6 - 2.4
V/V
mV
%
kΩ
Vocm/Vcm
0.97
100
10
1.5 - 3.5
50
25
4.5
0.9 - 1.1
200
5
0.9 - 1.1
200
5
30
30
6
30
30
6
V/V
mV
MΩ
V
dB
mA
mA
60
0.9 - 3.5
375 - 625
V
V
V
mW
V
Ω
DISTORTION AND NOISE RESPONSE
2nd harmonic distortion
3rd harmonic distortion
SNR
integrated output noise voltage
STATIC DC PERFORMANCE
Differential Amp
gain
output offset voltage
INL
Rin
Common-Mode Amp
gain
output offset voltage
Rin
input voltage range
power supply rejection ratio
supply current
supply current, power down
MISCELLANEOUS PERFORMANCE
power down input
VIL
VIH
power down dissipation
output voltage range
differential output resistance
DC
RL= ∞
CMOS levels
on
off
PDN = “Hi”
single output
0.5 - 4.8
1
4.5
45
0.7 - 3.9
500
MIN/MAX RATINGS
+25˚C
-40 to 85˚C
60
0.85 - 3.7
400 - 600
UNITS
NOTES
B
B
B
B
A
A
A
A
A
A
A
C
C
A
Min/max ratings are based on product characterization and simulation. Individual parameters are tested as noted. Outgoing quality levels are
determined from tested parameters.
Notes
Absolute Maximum Ratings
supply voltage
maximum input range
maximum output range (±V)
maximum operating temperature range
maximum junction temperature
maximum storage temperature range
maximum lead temperature (soldering 10 sec)
ESD rating (human body model)
A) J-level: spec is 100% tested at +25˚C, sample tested at +85˚C.
LC/MC-level: spec is 100% wafer probed at +25˚C.
B) J-level: spec is sample tested at +25˚C.
C) POWER DOWN must be 1V higher than Vcm.
±6V
±6V
0 to VCC
-40˚C to +85˚C
+175˚C
-65˚C to +150˚C
+300˚C
500V
Ordering Information
Model
CLC503AJE
Recommended Operating Conditions
supply voltage
input voltage
output voltage
ambient temperature range
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Temperature Range
Description
-40˚C to +85˚C
8-pin SOIC
Package Thermal Resistance
±4.5 to ±5.5Vdc
±1V
+0.8 to +3.75V
-40°C to +85°C
Package
SOIC (AJE)
2
qJC
qJA
65˚C/W
90˚C/W
Typical Performance Characteristics (VCC = + 5V, VEE = - 5V, Vcm = 2.25V, CL = 5pF, Vo = 4Vpp unless specified)(
Frequency Response vs. Vo
RL = 1kΩ
RL = 500Ω
RL = Open
10M
Vo = 1Vpp
10M
Frequency (Hz)
-82
Vin = 1.2Vpp
Vo = 2Vpp
Vcm = 2.25
Vcm = 1.75
-80
Distortion (dBc)
-82
2nd Harmonic Distortion vs. Amplitude
-60
RL = 2kΩ
Vcm = 2.75
-65
-86
-88
Vcm = 1.75
-90
Vcm = 1.25
-92
-94
-80
2MHz
-90
0.1M
0
10M
1
Frequency (Hz)
Frequency (Hz)
3
4
5
Settling Time vs. Capacitive Load
0.7
1.0
10MHz
0.6
5pf
Error (%)
2MHz
-85
Positive
0
Negative
-90
1MHz
10pf
20pf
40pf
0.5
0.5
5MHz
-80
2
Output Amplitude (Vpp)
Pulse Response CLC949 Driven By CLC503
3rd Harmonic Distortion vs. Amplitude
-70
5MHz
10MHz
-75
1MHz
-98
10M
-70
-85
-96
-84
10M
Frequency (Hz)
Vcm = 2.25
Vcm = 1.25
Distortion (dBc)
1M
Error (%)
Distortion (dBc)
Vcm = 2.75
RL = 2kΩ
CLC949 driven by CLC503
-1dB full scale input
100M
Vin = 1.2Vpp
Vo = 2Vpp
-84
-76
-75
SNR
60
3rd Harmonic Distortion vs. Frequency
2nd Harmonic Distortion vs. Frequency
0.1M
65
Frequency (Hz)
-74
-78
70
55
1M
1G
100M
Vo = 2Vpp
75
Distortion (dBc)
1M
SFDR
Vo = 3Vpp
SFDR (dBc), SNR (dB)
Vo = 1Vpp
SNR and SFDR
80
Normalized Magnitude (1dB/div)
Normalized Magnitude (1dB/div)
Frequency Response vs. RL
0.4
0.3
0.2
-0.5
0.1
-1.0
-0.1
-95
0
-100
0
1
2
3
4
0
5
20
40
60
80
100
10
Time (ns)
Output Amplitude (Vpp)
Equivalent Input Noise
1000
Power Down (PDN) Response
IB, VIO, vs. Temperature
100
100
Time (ns)
-5
2.18
-10
2.175
5
2.17
2.165
-20
IB
2.16
-25
10
2.155
-30
10k
100k
1M
10M
100M
-100
-50
Frequency (Hz)
PDN
2
1
0
0
50
100
150
Output
-2
Time (20ns/div)
Temperature (°C)
CLC949 Output When Driven By CLC503
3000
2500
Code Occurances
1k
3
-1
Voltage = 12nV/√Hz
0.1k
Amplitude (1V/div)
VIO (mV)
VIO
-15
IB (µA)
Voltage Noise (nV/√Hz)
4
Input Grounded
2000
1500
1000
500
0
2012
2013
2014
2015
2016
2017
Output Code
3
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CLC503 APPLICATIONS
APPLICATION CONSIDERATIONS
Figure 2 depicts the differential output voltage limits of
the CLC503.
Theory of Operation
Figure 1 is a simplified schematic of the CLC503.
R1
R2
-Vo
Output Voltage (V)
Q4
+Vin
PDN
R4
+Vo
B1
B2
Q4
+1
+Vo = Vcm +Vin
3.7
VCC
Q1
-1
Q2
Vcm
2.25
3.25V
Vcm
1.25V
0.8
-Vo = Vcm -Vin
Q5
-1
0
R3
I
I
I3
Icm
Figure 2: Differential Output Voltage
Centered around Vcm, the outputs are derived from the
following equations.
VEE
Current Mirror
R1 = R2
2 R1 = R3
R4 = 16R1
+Vo = Vcm + Vin
Figure 1: Simplified Block Diagram
-Vo = Vcm − Vin
The input voltage drives a unity gain buffer, B1, and
an inverting buffer, B2. These buffers drive emitter
followers, Q1 and Q2. Resistor, R3, is the gain set
resistor. The combination of B1, B2, Q1, Q2 and R3
form a transconductance stage. The input voltage
across R3 is converted to an in-phase and out-ofphase current through the collectors of Q1 and Q2. The
current through R3 is:
I3 =
Vodiff = +Vo – (-Vo ) = 2Vin
The input to output relationship is shown in Figure 3.
2Vin
R3
Vodiff = I3R1 + I3R 2
Vodiff = I3 (2R1)
Vodiff =
2Vin
(2R1)
R3
Vodiff
±1V
2Vpp
±1.4V max
±2V
4Vpp
±2.8V max
Pulling the power down line (PDN) high decreases the
quiescent supply current. This turns off the current
flowing in Q5, and therefore Q1 and Q2, allowing the
output voltages to drift high, to approximately 4.3V.
Since the signal is not significantly attenuated, PDN
does not effectively isolate the input from the output.
This part is not recommended for use as a multiplexer.
Refer to Pin Descriptions - Power Down pin section. No damage occurs to the device when PDN is
high and the input is driven to the supply voltage.
2R1 = R 3
The common mode voltage across R4 is converted
to a current. Transistor Q5 has a collector current
equal to:
VCC − Vcm − Vdiode
R4
Vin
Figure 3: Input vs. Output Relationship
R1 = R 2
Vodiff = 2Vin
Icm ≈
1
Input Voltage (V)
R 4 = 16R1
Pin Descriptions
PDN
VCC
The common mode current is scaled and mirrored back
to Q1 and Q2. These currents, I, are converted back to
a voltage at the collector load resistors, R1 and R2.
This forms the common-mode output voltage.
Vin
I = VCC − Vcm − Vdiode
R1
Vocm = VCC – Vdiode – R1I
I = 16Icm
Vocm = Vcm
1
2
+Vo
5
7
8
4
3 6
-Vo
VEE
Vcm
Figure 4: CLC503 Functional Pin Descriptions
4
■
Pin 1
Power Down (PDN): The power down pin takes
CMOS input levels. Use this to decrease the
power from 250mW to 40mW. This is not a
signal disable pin. A CMOS gate will drive this
input. The quiescent supply current will be
decreased when PDN is at least 1V higher than
Vcm. When the current is turned off, the output
voltage Vo, will go to approximately 4.3V. An
internal pull down resistor of 10k allows PDN to
be left open when not used.
Design Information
Load: The CLC503 is intended to drive high speed
CMOS analog-to-digital converters, such as the
CLC949. Resistive loading will affect the gain and
common mode offset. It is not recommended to drive
resistive loads below 10kΩ with this part. See Figure 5
for gain vs. load with specified range in device output
resistance.
2.5
Ro = 600Ω = Romax
Pin 2
Input Voltage (Vin): This is the signal input. The
recommended input range is ±1V. The linear
operating range is approximately ±1.4V This
input controls the differential output voltage.
Because of the closed loop nature of the transconductance stage, the transfer function is highly
linear. Refer to Output Voltage pin for output
signal limitations.
2
Gain (V/V)
■
1.5
Ro = 400Ω = Romin
1
0.5
0
100
1000
10000
100000
Load Resistance (Ω)
■
■
■
Pin 3
Ground (GND): Tie to low impedance analog
ground.
03 Fi
Figure 5: Gain vs. Resistive Load
Settling Time: The CLC503 settles to 0.1% in 15ns
with a 5pF load, the input capacitance of the CLC949.
Refer to the Settling Time vs. Capacitive Load plot in
the Typical Performance Characteristics section.
Pins 4 and 5
Power Supplies (VEE and VCC): For optimum
performance, use linear ±5V power supplies.
Use bypass capacitors of 0.1µF and 6.8µF on the
power supply lines to decrease any noise that
could be injected into the circuit by the power
supplies. Place the bypass capacitors as close
to the device pins as possible. Remove the
ground plane from the board underneath the
device to eliminate parasitic capacitance. Refer
to Printed Circuit Board Layout section for
more layout suggestions.
Power Dissipation
To calculate the power dissipation, PT, for the CLC503,
use the following equation:
PT = ICC (VCC − VEE )
Printed Circuit Board Layout
Pins 6 and 7
Output Voltage (-Vo and +Vo): These are the
differential signal output pins. The output voltage
at these pins is limited to 0.7V to 3.9V. The
output recovery time after exceeding these limits
is approximately 40ns. The output voltage can
be defined as:
The performance of the CLC503 is strongly dependent
on proper layout, and adequate power supply
decoupling. The parasitic capacitance at the output of
the CLC503 and the input to the CLC949, or any other
analog-to-digital converter, must be kept to a minimum.
Consider the following guidelines:
+Vo = Vcm + Vin
■
Use a ground plane.
■
Bypass power supply pins with monolithic
capacitors of 0.1µF and with 6.8µF tantalum
capacitors. Place the capacitors less than 0.1"
(3mm) from the pin.
■
Remove the ground plane underneath the
device and 0.1" (3mm) from all input/output
pads.
-Vo = Vcm − Vin
Vodiff = +Vo − (-Vo ) = 2Vin
Vocm =
■
+Vo − (-Vo )
= Vcm
2
Pin 8
Common-Mode Voltage (Vcm): This input sets
the common-mode output operating points. The
common mode input voltage can range from 1.5V
to 3.5V. Refer to Output Voltage pin discussion
for limitations on the output range.
Interfacing the CLC503 with the CLC949
The CLC503 can be easily interfaced with the CLC949
as shown in Figure 6. An evaluation board is available
for proto-typing and measurements.
5
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Comlinear CLC503
180MHz, Differential-Output Amplifier
 500Ω || RL 
A v new = A v old 

 500Ω 
ADC Clock
74AC04
Power Down
CLC503
Vin
VREFMO
0.1µF
PDN
Vcm
Vin
+Vo
VINP
GND
-Vo
VINN
VEE
VCC
where RL equals the input resistance of the A/D. The
impact of lower values of RL is shown in Figure 5. The
tolerance on the 500Ω is ±20%.
CLK
CLC949
12b/20MSPS ADC
0.1µF
6.8µF
0.1µF
6.8µF
BIASC
VCC
GND
■
0.1µF
-5V
+5V
Capacitive loading will affect the settling time.
The settling time equation is:
 100% 
t settle = R s ⋅ CL ⋅ ln 

 %settling 
Figure 6: Interfacing the CLC503 with the CLC949
Extended Use Considerations
Designed to drive the CLC949, the CLC503 can be
used with other analog-to-digital converters. The user
will want to consider the following parameters of the
device that the CLC503 will drive.
■
■
where Rs = 250Ω ±15% and %settling ≥ 0.1%. Refer
to the Settling Time vs. Capacitive Load plot in the
Typical Performance Characteristics section.
Input impedance of the A/D. Refer to Figure 5
for the Gain vs. Resistive Load. The CLC503
operates best when driving resistive loads
greater than 10kΩ and capacitive loads of less
than 10pF.
■
Resistive loading will affect the gain and common
mode offset. The gain setting resistors are
fixed internally. The voltage gain equation is:
Other considerations
■
Output signal swing must be within the
specified output range.
■
Common mode range must meet the
specified common mode range.
■
Distortion will be affected when Vin and
Vcm drive the output out of the linear
operating range.
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N
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6
Lit #150503-002