NSC CLC5526MSA

CLC5526
Digital Variable Gain Amplifier (DVGA)
General Description
The CLC5526 is a high performance, digitally controlled,
variable-gain amplifier (DVGA). It has been designed for use
in a broad range of mixed signal and digital communication
applications such as mobile radio, cellular base stations and
back-channel modems where automatic-gain-control (AGC)
is required to increase system dynamic range.
The CLC5526 has differential input and output, allowing
large signal swings on a single 5V rail. The input impedance
is 200Ω. The differential output impedance is 600Ω and is
designed to drive a 1 kΩ differential load. The output amplifier has excellent intermodulation performance. The
CLC5526 is designed to accept signals from RF elements
and maintain a terminated impedance environment.
The CLC5526 maintains a 350 MHz bandwidth over its entire gain and attenuation range from +30 dB to −12 dB. Internal clamping ensures very fast overdrive recovery. Two tone
intermodulation distortion is excellent: at 150 MHz, 1 Vpp it is
−64 dBc.
Input signals to the CLC5526 are scaled by an accurate, differential R-2R resistive ladder with an input impedance of
200Ω. A scaled version of the input is selected under digital
control and passed to the internal amplifier. The input common mode level is set at 2.4V via a bandgap referenced bias
generator which can be overridden by an external input.
Following the resistive ladder is a fixed, 30 dB gain amplifier.
The output stage common mode voltage of the CLC5526 is
set to 3V, by internal, positive supply connected resistors.
Digital control of the CLC5526 is accomplished by a 3-bit
parallel gain control input and a data valid pin to latch the
data. If the data is not latched, the DVGA is transparent to
gain control updates. All digital inputs are TTL/CMOS compatible.
A shutdown input reduces the CLC5526 supply currrent to a
few mA. During shutdown, the input termination is maintained and current attenuation settings are held.
The CLC5526 operates over the industrial temperature
range of −40˚C to +85˚C. The part is available in a 20-pin
SSOP package.
Features
n
n
n
n
n
350 MHz bandwidth
Differential input and output
Gain control: parallel w/data latching
Supply voltage: +5V
Supply current: 48 mA
Key Specifications
n Low two tone intermod:
distortion: −64 dBc @ 1 VPP, 150 MHz
24.5 dBm IP3, 150 MHz
n Low noise: 2.5 nV/√Hz (max gain),
9.3 dB noise figure (max gain)
n Wide gain range: +30 dB to −12 dB
n Gain step size: 6 dB
Applications
n
n
n
n
n
n
n
n
Cellular/PCS base stations
IF sampling receivers
Infrared/CCD imaging
Back-channel modems
Electro-optics
Instrumentation
Medical imaging
High definition video
Block Diagram
DS015016-2
© 1999 National Semiconductor Corporation
DS015016
www.national.com
CLC5526 Digital Variable Gain Amplifier (DVGA)
June 1999
Pin Configuration
Ordering Information
CLC5526MSA
20-Pin SSOP
CLC5526PCASM
Evaluation Board
DS015016-1
Pin Descriptions
Pin
Name
GND
Pin
No.
1, 5, 8, 10, 11, 13, 20
Description
Circuit ground.
Gain MSB
2
Gain Selection Most Significant Bit
Gain ISB
3
Gain Selection Data Bit
Gain LSB
4
Gain Selection Least Significant Bit
In+
6
Positive Differential Input
In−
7
Negative Differential Input
Ref Comp
9
VCC
16, 19
Reference Compensation
Positive Supply Voltage
Shutdown
18
Low Power Standby Control (Active High)
Latch Data
17
Data Latch Control (Active High)
Out+
15
Positive Differential Output
Out−
14
Negative Differential Output
Ref In
12
External Reference Input
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2
Absolute Maximum Ratings (Note 1)
Recommended Operating
Conditions
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Positive Supply Voltage (VCC)
Differential Voltage between any
Two Grounds
Analog Input Voltage Range
Digital Input Voltage Range
Output Short Circuit Duration
(one-pin to ground)
Junction Temperature
Storage Temperature Range
Lead Solder Duration (+300˚C)
+5V ± 5%
Positive Supply Voltage (VCC)
Differential Voltage between any
Two Grounds
−0.5V to +6V
< 200 mV
< 10 mV
Analog Input Voltage Range, AC
Coupled
−0.5V to +VCC
−0.5V to +VCC
Operating Temperature Range
Infinite
175˚C
−65˚C to +150˚C
10 sec
± 0.5V
−40˚C to +85˚C
Package Thermal Resistance
θJA
90˚C/W
Package
20-Pin SSOP
θJC
38˚C/W
Reliability Information
Transistor Count
300
Electrical Characteristics
The following specifications apply for VCC = +5V, RL = 1 kΩ maximum gain setting. Boldface limits apply for TA = Tmin =
−40˚C to Tmax = +85˚C, all other limits TA = 25˚C (Notes 2, 3, 4).
Symbol
Parameter
Conditions
Min
Typ
Max
Units
DYNAMIC PERFORMANCE
BW
Small-Signal Bandwidth
350
MHz
67
dBc
NOISE AND DISTORTION
2nd Harmonic Distortion
fIN = 150 MHz, 1
fIN = 250 MHz, 1
fIN = 150 MHz, 2
fIN = 250 MHz, 2
VPP
64
dBc
43
62
dBc
58
dBc
53
71
dBc
70
dBc
43
57
dBc
fIN = 250 MHz, 2 VPP
56
dBc
f1 = 149.9 MHz, f2 = 150.1 MHz,
1 VPP Composite
64
dBc
f1 = 149.9 MHz, f2 = 150.1 MHz,
2 VPP Composite
61
dBc
f1 = 249.9 MHz, f2 = 250.1 MHz,
1 VPP Composite
63
dBc
f1 = 249.9 MHz, f2 = 250.1 MHz,
2 VPP Composite
54
dBc
24.5
dBm
VPP
VPP
fIN = 150 MHz, 1 VPP
3rd Harmonic Distortion
IMD
Two Tone Intermodulation
Distortion
Two Tone, 3rd Order
Intermodulation
53
VPP
fIN = 250 MHz, 1 VPP
fIN = 150 MHz, 2 VPP
150 MHz
Minimum Gain Setting
2.2
nV/√Hz
Maximum Gain Setting
2.5
nV/√Hz
Maximum Gain Setting
9.3
dB
Differential Input Impedance
200
Ω
Differential Output Impedance
600
Ω
Thermal Noise
Noise Figure
ANALOG I/O
Input Signal Level (AC Coupled)
Maximum Gain
126
mV
Maximum Input Signal Level
Recommended
6
VPP
Maximum Output Signal Level
Recommended
4
VPP
8
VPP
Output Clipping
3
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Electrical Characteristics
(Continued)
The following specifications apply for VCC = +5V, RL = 1 kΩ maximum gain setting. Boldface limits apply for TA = Tmin =
−40˚C to Tmax = +85˚C, all other limits TA = 25˚C (Notes 2, 3, 4).
Symbol
Parameter
Conditions
Min
Typ
Max
Units
GAIN PARAMETERS
Maximum Gain
30
Minimum Gain
−12
dB
dB
Gain Step Size
6.02
dB
Gain Step Accuracy
(1 sigma)
0.03
dB
Cumulative Gain Step Error
(1 sigma)
0.085
dB
DIGITAL INPUTS/TIMING
Logic Compatibility
TTL/CMOS
V
VIL
Logic Input Low Voltage
VIH
Logic Input High Voltage
TSU
Setup Time
THOLD
Hold Time
3
ns
TPW
Minimum Pulse Width
3
ns
0.8
V
2.0
V
3
ns
POWER REQUIREMENTS
ICC
+5V Supply Current
48
Shutdown
9
60
mA
mA
Note 1: “Absolute Maximum Ratings” are limited values, to be applied individually, and beyond which the serviceability of the circuit may be impaired. Functional operability under any of these conditions is not necessarily implied. Exposure to maximum ratings for extended periods may affect device reliability.
Note 2: Limits are 100% tested at 25˚C.
Note 3: Typical specifications are the mean values of the distributions of deliverable amplifiers tested to date.
Note 4: Outgoing quality levels are determined from tested parameters.
Typical Performance Characteristics
Gain vs Frequency
(VCC = +5V, RL = 1 kΩ, max gain; unless specified)
Transconductance vs Frequency
DS015016-3
2nd and 3rd Harmonic Distortion
vs Frequency
DS015016-4
DS015016-5
2-Tone, 3rd Order Intermodulation
Output Intercept vs Frequency
Distortion vs Temperature
Distortion vs Gain Setting
DS015016-7
DS015016-6
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DS015016-8
Typical Performance Characteristics
(VCC = +5V, RL = 1 kΩ, max gain; unless
specified) (Continued)
6 dB Gain Step, Time Domain
Response
Gain Step Error Deviation
vs Gain Setting
DS015016-9
Noise Figure vs Gain Setting
Input Referred Thermal Noise vs
Gain Setting (Gain Block)
DS015016-10
Differential ZIN vs Frequency
DS015016-12
DS015016-13
5
DS015016-11
Differential ZOUT vs Frequency
DS015016-14
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Timing Diagram
DS015016-15
Truth Table
Gain Word
MSB
ISB
LSB
Gain (dB)
0
0
0
0
−12
1
0
0
1
−6
2
0
1
0
0
3
0
1
1
+6
4
1
0
0
+12
5
1
0
1
+18
6
1
1
0
+24
7
1
1
1
+30
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Note: Upon power-up the analog inputs are disconnected
from the internal amplifier. LATCH will need to be strobed
LOW before an analog output will be present!
Applications
DESCRIPTION
The CLC5526 is a digitally programmable, variable gain amplifier with the following features:
DIFFERENTIAL I/O CONSIDERATIONS
Analog inputs and outputs need to be AC coupled to prevent
DC loading of the common-mode voltages. If driving the
CLC5526 from a single-ended 50Ω source is required, a 1:2
transformer should be used to generate the differential inputs. As the differential input impedance of the CLC5526 is
200Ω, the 1:4 impedance ratio will allow for optimum matching to the 50Ω source. The secondary outputs of the transformer should be AC coupled to the CLC5526 analog inputs,
while the secondary center tap of the transformer should be
directly connected to the system ground.
The CLC5526 is designed to drive differential circuits, such
as the CLC5956 Analog to Digital convertor. Figure 2 below
shows a typical application of the CLC5526.
• 8 gain settings ranging from −12 to +30 dB in 6 dB steps
• Differential inputs and outputs (externally AC coupled)
• Self biased input common-mode voltage
• 3-bit parallel digital control
• Single +5V supply
• Low-Power standby mode
Please refer to Figure 1 for a representative block diagram.
DS015016-17
FIGURE 2. Differential I/O Connections
GAIN SELECTION
Gain levels can be decreased from the maximum value in −6
dB steps via the 3-bit digital inputs. Table 1 shows the gain
selection truth table for a 1000Ω differential load.
DRIVING LOADS
Actual gain of the CLC5526 will vary with the output load.
The device is designed to provide +30 dB maximum gain
with a 1000Ω differential load.
Each output of the CLC5526 contains an internal 300Ω resistor to the VCC rail. Actual gain calculations need to take
this in account with a given external load resistor. The effective load resistance can be used with the following equation
to calculate max gain values.
AV = 20 log (0.0843*Rleff)
Where: Rleff = Rint || Rext(diff)
Rint = 600Ω differential
TABLE 1. Gain Selection Truth Table
Chart 1 below shows maximum gain values over output load.
Resistor values are for differential loads.
DS015016-16
FIGURE 1. CLC5526 Block Diagram
Gain Word
MSB
ISB
LSB
Gain (dB)
0
0
0
0
−12
1
0
0
1
−6
2
0
1
0
0
3
0
1
1
+6
4
1
0
0
+12
5
1
0
1
+18
6
1
1
0
+24
7
1
1
1
+30
Gain settings can be calculated as follows:
GAIN = −12 dB + (Gain Word) * 6.02 dB
DS015016-18
Gain selection has two modes: Transparent or latched, depending on the LATCH input. If the LATCH input is held
LOW, then the device is in the transparent mode. Changes
on data inputs will result in direct changes to the gain setting.
Input data will be latched upon the LOW to HIGH transition of
LATCH. While LATCH is HIGH, digital data will be ignored
until LATCH is strobed low again.
Chart 1: Maximum Gain vs RLOAD
Stray capacitance at the output, along with the output load
value will form a pole, which can degrade the CLC5526
bandwidth. For a narrow-band application this problem can
be alleviated by using a tuned load, which will incorporate
7
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Applications
(Continued)
any stray parasitic impedance into a resonant circuit. By tuning the resonant load, full gain can be achieved with a given
resistive load.
A typical tuned load is shown below in Figure 3, where the
resonant frequency is tuned about 150 MHz.
The 1000Ω load in this circuit can represent the input impedance of the CLC5956 Analog to Digital converter. Actual values for the reactive components may vary slightly to account
for board and device parasitic elements.
DS015016-21
FIGURE 5. Diversity Receiver Chipset
SINAD vs Input Power
DS015016-19
FIGURE 3. CLC5526 Driving a Tuned Load
Layout Considerations
A proper printed circuit layout is essential for achieving high
frequency performance. National Semiconductor provides
evaluation boards for the CLC5526, which include input and
output transformers for impedance matching and single to
differential signal conversion.
Supply bypassing is required for best performance. Provide
a 6.8 µF Tantalum and 0.1 µF ceramic capacitor as close as
possible to the supply pin.
In addition, a 100 pF ceramic capacitor should be placed between the COMP pin (pin 9) and the system ground. This will
filter high frequency noise from the common-mode level.
Ceramic coupling capacitors should be used to AC couple
both the input and output. Actual values will depend upon the
signal frequency.
Typical Application
Although the CLC5526 can be used as a general purpose
digital variable gain amplifier, it was specifically designed to
provide the variable gain function in National’s Diversity Receiver Chipset. In this application, the CLC5526 drives a
tuned BPF and the CLC5956 Analog to Digital converter.
Digitized IF data is downsampled and tuned with the
CLC5902 dual digital tuner which also provides the AGC
control function. AGC data is fed back to the CLC5526. The
CLC5956 differential input impedance is 1000Ω, so with the
tuned load, full gain of the CLC5526 is achieved. Figure 4
shows the block diagram of the Diversity Receiver Chipset
application. Figure 5 shows the SINAD vs Input Power of the
diversity receiver chipset. For input power levels ranging
from 0 dB to −110 dB, the chip set provides a signal to noise
ratio in excess of the 9 dB required for a typical GSM system.
DS015016-20
FIGURE 4. Diversity Receiver Chipset Block Diagram
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Evaluation Board Layout and Schematic Diagram
DS015016-22
DS015016-23
CLC5526 Layer 1
CLC5526 Layer 2
DS015016-24
Evaluation Board Schematic
9
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CLC5526 Digital Variable Gain Amplifier (DVGA)
Physical Dimensions
inches (millimeters) unless otherwise noted
Millimeters only
20-Lead SSOP
Order Number CLC5526MSA
NS Package Number MSA20
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