AD AD8323ARU-REEL

a
FEATURES
Supports DOCSIS Standard for Reverse Path
Transmission
Gain Programmable in 0.75 dB Steps Over a 53.5 dB
Range
Low Distortion at 60 dBmV Output
–56 dBc SFDR at 21 MHz
–55 dBc SFDR at 42 MHz
Output Noise Level
–48 dBmV in 160 kHz
Maintains 75 ⍀ Output Impedance
Power-Up and Power-Down Condition
Upper Bandwidth: 100 MHz (Full Gain Range)
5 V Supply Operation
Supports SPI Interfaces
5 V CATV Line Driver Fine Step
Output Power Control
AD8323
FUNCTIONAL BLOCK DIAGRAM
VCC (7 PINS)
R1
VIN+
AD8323
VOUT+
DIFF OR
SINGLE
INPUT
AMP
VIN–
BYP
ATTENUATION
CORE
BUFFER
POWER
AMP
VOUT–
ZOUT DIFF =
75⍀
8
DECODE
R2
ZIN (SINGLE) = 800⍀
ZIN (DIFF) = 1.6k⍀
8
DATA LATCH
POWER-DOWN
LOGIC
8
SHIFT
REGISTER
APPLICATIONS
Gain-Programmable Line Driver
HFC High-Speed Data Modems
Interactive Set-Top Boxes
PC Plug-in Modems
General-Purpose Digitally Controlled Variable Gain Block
DATEN
DATA
CLK
GND (11 PINS)
PD
SLEEP
GENERAL DESCRIPTION
The AD8323 comprises a digitally controlled variable attenuator
of 0 dB to –53.5 dB, which is preceded by a low noise, fixed
gain buffer and is followed by a low distortion high power amplifier. The AD8323 accepts a differential or single-ended input
signal. The output is specified for driving a 75 Ω load, such as
coaxial cable.
Distortion performance of –56 dBc is achieved with an output
level up to 60 dBmV at 21 MHz bandwidth. A key performance
and cost advantage of the AD8323 results from the ability to maintain a constant 75 Ω output impedance during power-up and
power-down conditions. This eliminates the need for external 75 Ω
termination, resulting in twice the effective output voltage when
compared to a standard operational amplifier. In addition, this
device has a sleep mode function that reduces the quiescent
current to 4 mA.
–50
FO = 42MHz
PO = 60dBmV @ MAX GAIN
–55
DISTORTION – dBc
The AD8323 is a low-cost, digitally controlled, variable gain amplifier optimized for coaxial line driving applications such as cable
modems that are designed to the MCNS-DOCSIS upstream
standard. An 8-bit serial word determines the desired output gain
over a 53.5 dB range resulting in gain changes of 0.7526 dB/LSB.
HD3
–60
–65
HD2
–70
–75
0
8
16
24
32
40
48
56
GAIN CONTROL – DEC Code
64
72
Figure 1. Harmonic Distortion vs. Gain Control
The AD8323 is packaged in a low-cost 28-lead TSSOP, operates
from a single 5 V supply, and has an operational temperature
range of –40°C to +85°C.
REV. 0
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
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700
World Wide Web Site: http://www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 2000
(TA = 25ⴗC, VS = 5 V, RL = RIN = 75 ⍀, VIN = 116 mV p-p, VOUT measured through a 1:1
AD8323–SPECIFICATIONS transformer with an insertion loss of 0.5 dB @ 10 MHz unless otherwise noted.)
1
Parameter
INPUT CHARACTERISTICS
Specified AC Voltage
Noise Figure
Input Resistance
Conditions
Min
Output = 60 dBmV, Max Gain
Max Gain, f = 10 MHz
Single-Ended Input
Differential Input
OUTPUT CHARACTERISTICS
Bandwidth (–3 dB)
Bandwidth Roll-Off
Bandwidth Peaking
Output Noise Spectral Density
1 dB Compression Point
Differential Output Impedance
OVERALL PERFORMANCE
Second Order Harmonic Distortion
Third Order Harmonic Distortion
Gain Linearity Error
Output Settling to 1 mV
Due to Gain Change
Due to Input Step Change
Signal Feedthrough
POWER CONTROL
Power-Up Settling Time to 1 mV
Power-Down Settling Time to 1 mV
Between Burst Transients2
POWER SUPPLY
Operating Range
Quiescent Current
52.5
26.5
–27
Gain Code = 71 Dec
Gain Code = 0 Dec
Max
116
13.8
800
1600
2
Input Capacitance
GAIN CONTROL INTERFACE
Gain Range
Maximum Gain
Minimum Gain
Gain Scaling Factor
Typ
53.5
27.5
–26
0.7526
Unit
mV p-p
dB
Ω
Ω
pF
54.5
28.5
–25
dB
dB
dB
dB/LSB
All Gain Codes
f = 65 MHz
f = 65 MHz
Max Gain, f = 10 MHz
100
1.3
0
–34
Min Gain, f = 10 MHz
–48
Power-Down Mode, f = 10 MHz
–68
Max Gain, f = 10 MHz
Power-Up and Power-Down
18.5
75 ± 20%
MHz
dB
dB
dBmV in
160 kHz
dBmV in
160 kHz
dBmV in
160 kHz
dBm
Ω
f = 21 MHz, POUT = 60 dBmV @ Max Gain
f = 42 MHz, POUT = 60 dBmV @ Max Gain
f = 65 MHz, POUT = 60 dBmV @ Max Gain
f = 21 MHz, POUT = 60 dBmV @ Max Gain
f = 42 MHz, POUT = 60 dBmV @ Max Gain
f = 65 MHz, POUT = 60 dBmV @ Max Gain
f = 10 MHz, Code to Code
–77
–71
–64
–56
–55
–53
± 0.3
dBc
dBc
dBc
dBc
dBc
dBc
dB
Min to Max Gain
Max Gain, VIN = 0 V to 116 mV p-p
Max Gain, PD = 0, f = 42 MHz
60
30
–30
ns
ns
dBc
Max Gain, VIN = 0
Max Gain, VIN = 0
Equivalent Output = 31 dBmV
Equivalent Output = 60 dBmV
300
40
3
30
ns
ns
mV p-p
mV p-p
4.75
123
30
2
Power-Up Mode
Power-Down Mode
Sleep Mode
OPERATING TEMPERATURE
RANGE
–40
5
133
35
4
5.25
140
40
7
V
mA
mA
mA
+85
°C
NOTES
1
TOKO 617DB-A0070 used for above specifications. MACOM ETC-1-IT-15 can be substituted.
2
Between Burst Transients measured at the output of a 42 MHz diplexer.
Specifications subject to change without notice.
–2–
REV. 0
AD8323
LOGIC INPUTS (TTL/CMOS Compatible Logic) (DATEN, CLK, SDATA, PD, SLEEP, V
Parameter
Min
Logic “1” Voltage
Logic “0” Voltage
Logic “1” Current (VINH = 5 V) CLK, SDATA, DATEN
Logic “0” Current (VINL = 0 V) CLK, SDATA, DATEN
Logic “1” Current (VINH = 5 V) PD
Logic “0” Current (VINL = 0 V) PD
Logic “1” Current (VINH = 5 V) SLEEP
Logic “0” Current (VINL = 0 V) SLEEP
2.1
0
0
–600
50
–250
50
–250
TIMING REQUIREMENTS
CC
= 5 V: Full Temperature Range)
Typ
Unit
5.0
0.8
20
–100
190
–30
190
–30
V
V
nA
nA
µA
µA
µA
µA
(Full Temperature Range, VCC = 5 V, TR = TF = 4 ns, fCLK = 8 MHz unless otherwise noted.)
Parameter
Min
Clock Pulsewidth (TWH)
Clock Period (TC)
Setup Time SDATA vs. Clock (TDS)
Setup Time DATEN vs. Clock (TES)
Hold Time SDATA vs. Clock (TDH)
Hold Time DATEN vs. Clock (TEH)
Input Rise and Fall Times, SDATA, DATEN, Clock (TR, TF)
16.0
32.0
5.0
15.0
5.0
3.0
Typ
TDS
VALID DATA WORD G1
MSB. . . .LSB
SDATA
VALID DATA WORD G2
TC
TWH
CLK
TES
TEH
8 CLOCK CYCLES
DATEN
GAIN TRANSFER (G1)
GAIN TRANSFER (G2)
TOFF
PD
TGS
TON
ANALOG
OUTPUT
PEDESTAL
SIGNAL AMPLITUDE (p-p)
Figure 2. Serial Interface Timing
VALID DATA BIT
SDATA MSB
MSB-1
TDS
MSB-2
TDH
CLK
Figure 3. SDATA Timing
REV. 0
Max
–3–
Max
Unit
10
ns
ns
ns
ns
ns
ns
ns
AD8323
PIN CONFIGURATION
ABSOLUTE MAXIMUM RATINGS*
Supply Voltage +VS
Pins 5, 9, 10, 19, 20, 23, 27 . . . . . . . . . . . . . . . . . . . . . . 6 V
Input Voltages
Pins 25, 26 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ± 0.5 V
Pins 1, 2, 3, 6, 7 . . . . . . . . . . . . . . . . . . . . . –0.8 V to +5.5 V
Internal Power Dissipation
TSSOP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0.9 W
Operating Temperature Range . . . . . . . . . . . –40°C to +85°C
Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C
Lead Temperature, Soldering 60 seconds . . . . . . . . . . . 300°C
*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.
DATEN
1
28
SDATA
2
27
VCC
CLK
3
26
VIN–
GND
4
25
VIN+
VCC
5
24
GND
23
VCC
PD
6
SLEEP
7
GND
8
VCC
AD8323
GND
GND
TOP VIEW
(Not to Scale) 21 BYP
22
9
20
VCC
VCC 10
19
VCC
GND 11
18
GND
GND 12
17
GND
GND 13
16
GND
OUT– 14
15
OUT+
ORDERING GUIDE
Model
Temperature Range
Package Description
␪JA
Package Option
AD8323ARU
AD8323ARU-REEL
AD8323-EVAL
–40°C to +85°C
–40°C to +85°C
28-Lead TSSOP
28-Lead TSSOP
Evaluation Board
67.7°C/W*
67.7°C/W*
RU-28
RU-28
*Thermal Resistance measured on SEMI standard 4-layer board.
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection. Although
the AD8323 features proprietary ESD protection circuitry, permanent damage may occur on
devices subjected to high-energy electrostatic discharges. Therefore, proper ESD precautions are
recommended to avoid performance degradation or loss of functionality.
WARNING!
ESD SENSITIVE DEVICE
PIN FUNCTION DESCRIPTIONS
Pin No.
Mnemonic
Description
1
DATEN
2
SDATA
3
CLK
4, 8, 11,12,
13, 16, 17, 18,
22, 24, 28
5, 9, 10, 19,
20, 23, 27
6
7
GND
Data Enable Low Input. This port controls the 8-bit parallel data latch and shift register. A Logic
0-to-1 transition transfers the latched data to the attenuator core (updates the gain) and simultaneously inhibits serial data transfer into the register. A 1-to-0 transition inhibits the data latch
(holds the previous gain state) and simultaneously enables the register for serial data load.
Serial Data Input. This digital input allows for an 8-bit serial (gain) word to be loaded into the
internal register with the MSB (Most Significant Bit) first.
Clock Input. The clock port controls the serial attenuator data transfer rate to the 8-bit masterslave register. A Logic 0-to-1 transition latches the data bit and a 1-to-0 transfers the data bit to
the slave. This requires the input serial data word to be valid at or before this clock transition.
Common External Ground Reference.
VCC
Common Positive External Supply Voltage. A 0.1 µF capacitor must decouple each pin.
PD
SLEEP
14
15
21
25
OUT–
OUT+
BYP
VIN+
26
VIN–
Logic “0” powers down the part. Logic “1” powers up the part.
Low Power Sleep Mode. In the Sleep mode, the AD8323’s supply current is reduced to 4 mA. A
Logic “0” powers down the part (High ZOUT State) and a Logic “1” powers up the part.
Negative Output Signal.
Positive Output Signal.
Internal Bypass. This pin must be externally ac-coupled (0.1 µF cap).
Noninverting Input. DC-biased to approximately VCC/2. For single-ended inverting operation,
use a 0.1 µF decoupling capacitor and a 39.2 Ω resistor between VIN+ and ground.
Inverting Input. DC-biased to approximately VCC/2. Should be ac-coupled with a 0.1 µF capacitor.
–4–
REV. 0
Typical Performance Characteristics– AD8323
34
1:1
IN
VIN–
VIN+
31
0.1␮F
VIN
RL 75⍀
OUT–
82.5⍀
OUT+
VIN+
0.1␮F
RL
75⍀
28
25
CL = 50pF
CL = 20pF
CL = 10pF
GND
0.1␮F
39.2⍀
CL
CL = 0pF
OUT
0.1␮F
VIN–
RTI
TOKO 617DB–A0070
1:1
GAIN – dB
VCC
POUT = 60dBmV
@ MAX GAIN
OUT
22
19
1
10
FREQUENCY – MHz
100
TPC 4. AC Response for Various Cap Loads
TPC 1. Basic Test Circuit
–30
1.5
f = 10MHz
PD = 1
0.5
OUTPUT NOISE – dBmV in 160kHz
GAIN ERROR – dB
1.0
f = 10MHz
0.0
f = 5MHz
f = 42MHz
–0.5
–1.0
–34
–38
–42
–46
f = 65MHz
–1.5
–50
0
8
16
24
32
40
48
GAIN CONTROL – Decimal
56
64
72
0
8
16
24
32
40
48
GAIN CONTROL – Decimal
56
64
72
TPC 5. Output Referred Noise vs. Gain Control
TPC 2. Gain Error vs. Gain Control
0
40
PD = 0
VIN = 116mV p-p
71D
30
–20
FEEDTHROUGH – dB
GAIN – dB
20
46D
10
0
23D
–10
–20
00D
MAX GAIN
–40
–60
MIN GAIN
–80
–30
–40
0.1
–100
1
10
FREQUENCY – MHz
100
1k
0.1
10
FREQUENCY – MHz
100
1k
TPC 6. Input Signal Feedthrough vs. Frequency
TPC 3. AC Response
REV. 0
1
–5–
AD8323
85
–60
RTI = 82.5⍀
80
POUT = 62dBmV
@ MAX GAIN
PD = 0
IMPEDANCE – ⍀
DISTORTION – dBc
–65
POUT = 61dBmV
@ MAX GAIN
–70
POUT = 60dBmV
@ MAX GAIN
–75
–80
75
PD = 1
70
65
60
POUT = 58dBmV
@ MAX GAIN
–85
5
15
25
35
45
55
FUNDAMENTAL FREQUENCY – MHz
55
65
1
10
FREQUENCY – MHz
TPC 7. Second Order Harmonic Distortion vs. Frequency
for Various Output Levels
TPC 10. Input Impedance vs. Frequency
–45
80
75
POUT = 61dBmV
@ MAX GAIN
PD = 1
IMPEDANCE – ⍀
POUT = 62dBmV
@ MAX GAIN
–50
DISTORTION – dBc
100
–55
POUT = 60dBmV
@ MAX GAIN
–60
70
PD = 0
65
60
55
POUT = 58dBmV
@ MAX GAIN
–65
5
15
25
35
45
55
FUNDAMENTAL FREQUENCY – MHz
50
65
TPC 8. Third Order Harmonic Distortion vs. Frequency for
Various Output Levels
1
10
FREQUENCY – MHz
100
TPC 11. Output Impedance vs. Frequency
140
60
POUT = 60dBmV
@ MAX GAIN
50
130
PD = 1
120
40
110
100
20
+ICC – mA
POUT – dBmV
30
10
0
90
80
70
60
–10
50
–20
–40
41.0 41.2
PD = 0
40
–30
30
41.4
41.6
41.8 42.0 42.2 42.4
FREQUENCY – MHz
42.6
42.8
20
–50
43.0
TPC 9. Two-Tone Intermodulation Distortion
–25
0
25
50
TEMPERATURE – ⴗC
75
100
TPC 12. Supply Current vs. Temperature
–6–
REV. 0
AD8323
APPLICATIONS
General Application
The AD8323 is primarily intended for use as the upstream
power amplifier (PA) in DOCSIS (Data Over Cable Service
Interface Specifications) certified cable modems and CATV settop boxes. Upstream data is modulated in QPSK or QAM format, and done with DSP or a dedicated QPSK/QAM modulator.
The amplifier receives its input signal from the QPSK/QAM
modulator or from a DAC. In either case the signal must be
low-pass filtered before being applied to the amplifier. Because
the distance from the cable modem to the central office will vary
with each subscriber, the AD8323 must be capable of varying its
output power by applying gain or attenuation to ensure that all
signals arriving at the central office are of the same amplitude.
The upstream signal path contains components such as a transformer and diplexer that will result in some amount of power loss.
Therefore, the amplifier must be capable of providing enough
power into a 75 Ω load to overcome these losses without sacrificing the integrity of the output signal.
The gain transfer function is as follows:
AV = 27.5 dB – (0.7526 dB × (71 – CODE)) for 0 ≤ CODE ≤ 71
where AV is the gain in dB and CODE is the decimal equivalent
of the 8-bit word.
Valid gain codes are from 0 to 71. Figure 4 shows the gain
characteristics of the AD8323 for all possible values in an 8-bit
word. Note that maximum gain is achieved at Code 71. From
Code 72 through 127 the 5.25 dB of attenuation from the vernier stage is being applied over every eight codes, resulting in
the sawtooth characteristic at the top of the gain range. Because
the eighth bit is a “don’t care” bit, the characteristic for codes 0
through 127 repeats from Codes 128 through 255.
28
21
14
The AD8323 is composed of four analog functions in the
power-up or forward mode. The input amplifier (preamp) can
be used single-ended or differentially. If the input is used in
the differential configuration, it is imperative that the input
signals are 180 degrees out of phase and of equal amplitudes.
This will ensure the proper gain accuracy and harmonic
performance. The preamp stage drives a vernier stage that
provides the fine tune gain adjustment. The 0.7526 dB step
resolution is implemented in this stage and provides a total of
approximately 5.25 dB of attenuation. After the vernier stage,
a DAC provides the bulk of the AD8323’s attenuation (8 bits
or 48 dB). The signals in the preamp and vernier gain blocks
are differential to improve the PSRR and linearity. A differential current is fed from the DAC into the output stage, which
amplifies these currents to the appropriate levels necessary
to drive a 75 Ω load. The output stage utilizes negative feedback to implement a differential 75 Ω output impedance. This
eliminates the need for external matching resistors needed in
typical video (or video filter) termination requirements.
SPI Programming and Gain Adjustment
Gain programming of the AD8323 is accomplished using a
serial peripheral interface (SPI) and three digital control lines,
DATEN, SDATA, and CLK. To change the gain, eight bits of
data are streamed into the serial shift register through the
SDATA port. The SDATA load sequence begins with a falling
edge on the DATEN pin, thus activating the CLK line. Although
the CLK line is now activated, no change in gain is yet observed
at the output of the amplifier. With the CLK line activated, data
on the SDATA line is clocked into the serial shift register Most
Significant Bit (MSB) first, on the rising edge of each CLK
pulse. Because only a 7-bit shift register is used, the MSB of the
8-bit word is a “don’t care” bit and is shifted out of the register
on the eighth clock pulse. A rising edge on the DATEN line
latches the contents of the shift register into the attenuator core
resulting in a well controlled change in the output signal level.
The serial interface timing for the AD8323 is shown in Figures 2
and 3. The programmable gain range of the AD8323 is –26 dB
to +27.5 dB and scales 0.7526 dB per least significant bit (LSB).
Because the AD8323 was characterized with a TOKO transformer,
the stated gain values already take into account the losses associated with the transformer.
REV. 0
GAIN – dB
Operational Description
7
0
–7
–14
–21
–28
0
32
64
96
128
160
GAIN CODE – Decimal
192
224
256
Figure 4. Gain vs. Gain Code
Input Bias, Impedance, and Termination
The VIN+ and VIN– inputs have a dc bias level of approximately
VCC/2, therefore the input signal should be ac-coupled. The
differential input impedance is approximately 1600 Ω while the
single-ended input impedance is 800 Ω. If the AD8323 is being
operated in a single-ended input configuration with a desired
input impedance of 75 Ω, the VIN+ and VIN– inputs should be
terminated as shown in Figure 5. If an input impedance other
than 75 Ω is desired, the values of R1 and R2 in Figure 5 can be
calculated using the following equations:
ZIN = R1 800
R2 = ZIN R1
ZIN = 75⍀
–
R1 = 82.5⍀
AD8323
+
R2 = 39.2⍀
Figure 5. Single-Ended Input Termination
–7–
AD8323
input and output traces should be kept as short and symmetrical
as possible. In addition, the input and output traces should be
kept far apart in order to minimize coupling (crosstalk) through
the board. Following these guidelines will improve the overall
performance of the AD8323 in all applications.
Output Bias, Impedance, and Termination
The differential output pins VOUT+ and VOUT– are also biased to
a dc level of approximately VCC/2. Therefore, the outputs should
be ac-coupled before being applied to the load. This may be
accomplished by connecting 0.1 µF capacitors in series with the
outputs as shown in the typical applications circuit of Figure 6.
The differential output impedance of the AD8323 is internally
maintained at 75 Ω, regardless of whether the amplifier is in
forward transmit mode or reverse power-down mode, eliminating the need for external back termination resistors. A 1:1
transformer (TOKO #617DB-A0070) is used to couple
the amplifier’s differential output to the coaxial cable while
maintaining a proper impedance match. If the output signal
is being evaluated on standard 50 Ω test equipment, a 75 Ω to
50 Ω pad must be used to provide the test circuit with the
correct impedance match.
Initial Power-Up
When the 5 V supply is first applied to the VCC pins of the
AD8323, the gain setting of the amplifier is indeterminate.
Therefore, as power is first applied to the amplifier, the PD pin
should be held low (Logic 0) thus preventing forward signal
transmission. After power has been applied to the amplifier, the
gain can be set to the desired level by following the procedure in
the SPI Programming and Gain Adjustment section. The PD
pin can then be brought from Logic 0 to 1, enabling forward
signal transmission at the desired gain level.
Asynchronous Power-Down
Power Supply Decoupling, Grounding, and Layout
Considerations
The asynchronous PD pin is used to place the AD8323 into
“Between Burst” mode while maintaining a differential output
impedance of 75 Ω. Applying a Logic 0 to the PD pin activates
the on-chip reverse amplifier, providing a 74% reduction in
consumed power. The supply current is reduced from approximately 133 mA to approximately 35 mA. In this mode of
operation, between burst noise is minimized and the amplifier
can no longer transmit in the upstream direction. In addition to
the PD pin, the AD8323 also incorporates an asynchronous
SLEEP pin, which may be used to place the amplifier in a high
output impedance state and further reduce the supply current to
approximately 4 mA. Applying a Logic 0 to the SLEEP pin
places the amplifier into SLEEP mode. Transitioning into or
out of SLEEP mode will result in a transient voltage at the output
of the amplifier. Therefore, use only the PD pin for DOCSIS
compliant “Between Burst” operation.
Careful attention to printed circuit board layout details will
prevent problems due to associated board parasitics. Proper RF
design technique is mandatory. The 5 V supply power should be
delivered to each of the VCC pins via a low impedance power bus
to ensure that each pin is at the same potential. The power bus
should be decoupled to ground with a 10 µF tantalum capacitor
located in close proximity to the AD8323. In addition to the
10 µF capacitor, each VCC pin should be individually decoupled to
ground with a 0.1 µF ceramic chip capacitor located as close to
the pin as possible. The pin labeled BYP (Pin 21) should also be
decoupled with a 0.1 µF capacitor. The PCB should have a lowimpedance ground plane covering all unused portions of the
component side of the board, except in the area of the input and
output traces (see Figure 11). It is important that all of the
AD8323’s ground pins are connected to the ground plane to
ensure proper grounding of all internal nodes. The differential
5V
10␮F
25V
0.1␮F
AD8323TSSOP
DATEN
SDATA
CLK
0.1␮F
PD
0.1␮F
SLEEP
0.1␮F
DATEN
SDATA
CLK
GND1
VCC
PD
SLEEP
GND2
VCC1
VCC2
GND3
GND4
GND5
OUT–
0.1␮F
ZIN = 150⍀
VIN–
VIN+
GND10
VCC5
GND9
BYP
VCC4
VCC3
GND8
GND7
GND6
OUT+
VIN–
0.1␮F
GND11
VCC6
165⍀
0.1␮F
VIN+
0.1␮F
0.1␮F
0.1␮F
0.1␮F
0.1␮F
TOKO 617DB-A0070
TO DIPLEXER ZIN = 75⍀
Figure 6. Typical Applications Circuit
–8–
REV. 0
AD8323
Distortion, Adjacent Channel Power, and DOCSIS
In order to deliver 58 dBmV of high fidelity output power
required by DOCSIS, the PA should be able to deliver about
60 dBmV to 61 dBmV in order to make up for losses associated
with the transformer and diplexer. It should be noted that the
AD8323 was characterized with the TOKO 617DB-A0070
transformer. TPC 7 and TPC 8 show the AD8323 second and
third harmonic distortion performance versus fundamental
frequency for various output power levels. These figures are
useful for determining the inband harmonic levels from 5 MHz to
65 MHz. Harmonics higher in frequency will be sharply attenuated by the low-pass filter function of the diplexer. Another
measure of signal integrity is adjacent channel power or ACP.
DOCSIS section 4.2.9.1.1 states, “Spurious emissions from a
transmitted carrier may occur in an adjacent channel that could
be occupied by a carrier of the same or different symbol rates.”
Figure 7 shows the measured ACP for a 16 QAM, 60 dBmV
signal, taken at the output of the AD8323 evaluation board (see
Figure 13 for evaluation board schematic). The transmit channel width and adjacent channel width in Figure 7 correspond to
symbol rates of 160 KSYM/SEC. Table I shows the ACP results for
the AD8323 for all conditions in DOCSIS Table 4-7 “Adjacent
Channel Spurious Emissions.”
RBW 500 Hz RF ATT 40dB
–10 VBW 5 kHz
SWT 12s UNIT dBm
–20
CH PWR
ACP UP
ACP LOW
5.44 dBm
–52.99 dB
–54.36 dB
Comparing the computed noise power of –48 dBmV to the
8 dBmV signal yields –56 dBc, which meets the required level of
–53 dBc set forth in DOCSIS Table 4-8. As the AD8323’s gain is
increased from this minimum value, the output signal increases at a
faster rate than the noise, resulting in a signal to noise ratio that
improves with gain. In transmit disable mode, the output noise
spectral density computed over 160 KSYM/SECOND is 1.0 nV/√Hz
or –68 dBmV.
Evaluation Board Features and Operation
The AD8323 evaluation board (Part # AD8323-EVAL) and
control software can be used to control the AD8323 upstream
cable driver via the parallel port of a PC. A standard printer
cable connected between the parallel port and the evaluation
board is used to feed all the necessary data to the AD8323 by
means of the Windows-based, Microsoft Visual Basic control
software. This package provides a means of evaluating the
amplifier by providing a convenient way to program the gain/
attenuation as well as offering easy control of the amplifiers’
asynchronous PD and SLEEP pins. With this evaluation kit the
AD8323 can be evaluated with either a single-ended or differential
input configuration. The amplifier can also be evaluated with or
without the PULSE diplexer in the output signal path. To remove
the diplexer from the signal path, move the 0 Ω chip resistor at
JP5 so the output signal is directed away from the diplexer
and toward the CABLE port of the evaluation board. Also,
remove the 0 Ω resistor at JP4. A schematic of the evaluation
board is provided in Figure 13.
Overshoot on PC Printer Ports
–30
–40
–50
–60
C0
–70
C0
CU1
Transformer and Diplexer
CL1
CL1
–80
CENTER 10 MHz
The data lines on some PC parallel printer ports have excessive
overshoot that may cause communications problems when presented to the CLK pin of the AD8323 (TP5 on the evaluation
board). The evaluation board was designed to accommodate a
series resistor and shunt capacitor (R1 and C15) to filter the
CLK signal if required.
CU1
60 kHz
F1
SPAN 600 kHz
Figure 7. Adjacent Channel Power
Table I. ACP Performance for All DOCSIS Conditions
(All Values in dBc)
TRANSMIT
ADJACENT CHANNEL SYMBOL RATE
CHANNEL
SYMBOL RATE 160 KSYM/SEC 320 KSYM/SEC 640 KSYM/SEC 1280 KSYM/SEC 2560 KSYM/SEC
160 KSYM/SEC
–53.0
–53.8
–55.0
–56.6
–56.3
320 KSYM/SEC
–52.7
–53.4
–53.8
–54.8
–55.4
640 KSYM/SEC
–53.8
–52.9
–53.3
–53.6
–54.2
1280 KSYM/SEC
–53.7
–53.4
–53.0
–53.3
–53.5
2560 KSYM/SEC
–55.4
–54.0
–53.6
–53.1
–53.3
Noise and DOCSIS
At minimum gain, the AD8323’s output noise spectral density is
10 nV/√Hz measured at 10 MHz. DOCSIS Table 4-8, “Spurious
Emissions in 5 MHz to 42 MHz,” specifies the output noise for
various symbol rates. The calculated noise power in dBmV for
160 KSYM/SECOND is:
A 1:1 transformer is needed to couple the differential outputs of
the AD8323 to the cable while maintaining a proper impedance
match. The specified transformer is available from TOKO (Part
# 617DB-A0070); however, MA/COM part # ETC-1-1T-15
can also be used. The evaluation board is equipped with the
TOKO transformer, but is also designed to accept the MA/
COM transformer. The PULSE diplexer included on the
evaluation board provides a high-order low-pass filter function,
typically used in the upstream path. The ability of the PULSE
diplexer to achieve DOCSIS compliance is neither expressed
nor implied by Analog Devices Inc. Data on the diplexer should
be obtained from PULSE.
Differential Inputs
The AD8323-EVAL evaluation board is designed to accommodate
a Mini-Circuits T1-6T-KK81 1:1 transformer for the purpose of
converting a single-ended (ground-referenced) input signal to
differential inputs. Figure 8 and the following paragraphs identify
two options for providing differential input signals to the AD8323
evaluation board.



2
 10 nV 



 × 160 kHz   + 60 = –48 dBmV
 20 log  


Hz






REV. 0
–9–
AD8323
Single-Ended-to-Differential Input (Figure 8, Option 1)
Installing the Visual Basic Control Software
Install the Mini-Circuits T1-6T-KK81 1:1 transformer in the
T1 location of the evaluation board. Place 0 Ω chip resistors at
locations JP1, JP2, and JP3 such that the signal coming in VIN+
is directed toward the transformer and the differential signal
coming out of the transformer is directed toward TP13 and
TP14. For 75 Ω input impedance, install 39.2 Ω resistors in R5
and R6 located on the back side of the evaluation board. In this
configuration the input signal must be applied to the VIN+ port
of the evaluation board from a single-ended 75 Ω signal source.
For input impedances other than 75 Ω, the correct value for R5
and R6 can be computed using the following equation:
To install the “CABDRIVE_23” evaluation board control software, close all Windows applications and then run “SETUP.EXE”
located on Disk 1 of the AD8323 Evaluation Software. Follow
the on-screen instructions and insert Disk 2 when prompted to
do so. Enter the path of the directory into which the software
will be installed and select the button in the upper left corner to
complete the installation.
(R5 = R6 = R), Desired Impedance = 2 × (R 800)
Differential Input (Figure 8, Option 2)
If a differential signal source is available, it may be applied
directly to both the VIN+ and VIN– input ports of the evaluation
board. In this case, 0 Ω chip resistors should be placed at locations R8, JP1, JP2, and JP3 such that the VIN+ and VIN– signals
are directed toward TP13 and TP14. Referring to Figure 8,
Option 2, a differential input impedance of 150 Ω can be
achieved by using a 165 Ω resistor for R7. For input impedances other than 150 Ω, the correct value for R7 can be computed
using the following equation:
(
Desired Impedance = R7 1600
)
R6
DIFF IN
AD8323
T1
R5
OPTION 1 DIFFERENTIAL INPUT TERMINATION
VIN+
R7
Running the Software
To invoke the control software, go to START -> PROGRAMS
-> CABDRIVE_23, or select the AD8323.EXE icon from the
directory containing the software.
Controlling the Gain/Attenuation of the AD8323
The slide bar controls the AD8323’s gain/attenuation, which is
displayed in dB and in V/V. The gain scales at 0.7526 dB per
LSB with the valid codes being from decimal 0 to 71. The gain
code (i.e., position of the slide bar) is displayed in decimal, binary,
and hexadecimal (see Figure 9).
POWER-UP, POWER-DOWN AND SLEEP
The “Power-Up” and “Power-Down” buttons select the mode
of operation of the AD8323 by controlling the logic level on the
asynchronous PD pin. The “Power-Up” button applies a
Logic 1 to the PD pin putting the AD8323 in forward transmit
mode. The “Power-Down” button applies a Logic 0 to the PD
pin selecting reverse mode, where the forward signal transmission
is disabled while a back termination of 75 Ω is maintained.
Checking the “Enable SLEEP Mode” box applies a Logic 0 to
the asynchronous SLEEP pin, putting the AD8323 into SLEEP
mode.
Memory Section
The “MEMORY” section of the software provides a convenient
way to alternate between two gain settings. The “X->M1” button stores the current value of the gain slide bar into memory
while the “RM1” button recalls the stored value, returning the
gain slide bar to that level. The “X->M2” and “RM2” buttons
work in the same manner.
AD8323
VIN–
OPTION 2 DIFFERENTIAL INPUT TERMINATION
Figure 8. Differential Input Termination Options
–10–
REV. 0
AD8323
EVALUATION BOARD FEATURES AND OPERATION
Figure 9. Screen Display of Windows-Based Control Software
REV. 0
–11–
AD8323
Figure 10. Evaluation Board—Assembly (Component Side)
Figure 11. Evaluation Board Layout (Component Side)
–12–
REV. 0
AD8323
Figure 12. Evaluation Board—Solder Side
REV. 0
–13–
1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
AGND
J2
BLK
TP20
J1
1
–14–
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
AMP-552742
+ C18
10␮F
25V
RED
TP15
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
PD
SLEEP
DATEN
SDATA
CLK
DATEN
SDATA
WHT
TP1
WHT
TP3
C17
DNI
R12
WHT 0⍀
TP19
C16
DNI
R11
WHT 0⍀
C15
DNI
R1
WHT 0⍀
TP17
TP2
C14
DNI
R2
WHT 0⍀
TP4
C4
0.1␮F
C3
0.1␮F
C1
0.1␮F
1
2
3
4
5
6
7
8
9
10
11
12
13
14
WHT
CLK
WHT
PD
TP18
WHT
SPARE
TP16
WHT
SLEEP
TP5
TP6
AD8323TSSOP
28
GND11
DATEN
27
VCC6
SDATA
26
VIN–
CLK
25
VIN+
GND1
24
GND10
VCC
23
VCC5
PD
U1
22
GND9
SLEEP
21
GND2
BYP
20
VCC4
VCC1
19
VCC2
VCC3
18
GND3
GND8
17
GND4
GND7
16
GND5
GND6
15
OUT–
OUT+
TP7
DNI
C10
0.1␮F
TP12
DNI C11
0.1␮F
TP8
DNI
1
2
3
TP11
DNI
C2
0.1␮F
C7
0.1␮F
C6
0.1␮F
C5
0.1␮F
C8
0.1␮F
T2A DNI
1:1
ETCC1-1T
R6
39.2⍀
C12
0.1␮F
R5
82.5⍀
C13
0.1␮F
5
4
TP9
DNI
1
5
TP13
YEL
R7
DNI
TP14
YEL
T2B
1:1
NC = 2
TOKO-B4F
1 JP3
B
3
A
2
1
2
3
A
B
JP1
1
3
2
3
4
T1 DNI
1:1
NC = 5
6
4
R9
DNI
JP5
R3
0⍀
2 B 1
3
A
U2
JP2 1
B
A
3
2
R8
0⍀
AGND;3,4,5
TP10
DNI
JP4
R4
DNI
AGND;3,4,5
S1
CABLE
TP21
DNI HPP
S4
AGND;3,4,5
TP22
DNI
S3
VIN+
S2
VIN–
AGND;3,4,5
18
1
G1
A
17
G2
16
3
G3
A–B
15
G4
5
14
B
G5
13
G6
12
G7
11
9 PULSEB5008
G8
OUT = 2,4,6,7,8 G9 10
VCC
AD8323
Figure 13. Evaluation Board Schematic
REV. 0
AD8323
EVALUATION BOARD BILL OF MATERIALS
AD8323 Evaluation Board Rev. C SINGLE-ENDED INVERTING INPUT – Revised – June 22, 2000
Qty.
Description
Vendor
Ref Desc.
1
12
6
1
1
2
10
1
1
3
4
1
2
1
1
1
1
4
4
2
2
2
3
10 µF 16 V. ‘C’ size tantalum chip capacitor
0.1 µF 50 V. 1206 size ceramic chip capacitor
0 Ω 1/8 W. 1206 size chip resistor
39.2 Ω 1% 1/8 W. 1206 size chip resistor
82.5 Ω 1% 1/8 W. 1206 size chip resistor
Yellow Test Point [INPUTS] (Bisco TP104-01-04)
White Test Point [DATA] (Bisco TP104-01-09)
Red Test Point [VCC] (Bisco TP104-01-02)
Black Test Point [A.GND] (Bisco TP104-01-00)
0 Ω 0805 size chip resistors
75 Ω right-angle BNC Telegartner # J01003A1949
Centronics type 36 pin Right-Angle Connector
5-way Metal Binding Post (E F Johnson # 111-2223-001)
1:1 Transformer TOKO # 617DB - A0070
Diplexer PULSE*
AD8323 (TSSOP) UPSTREAM Cable Driver
AD8323 REV. C Evaluation PC board
#4 - 40 × 1/4 inch STAINLESS panhead machine screw
#4 - 40 × 3/4 inch long aluminum round stand-off
# 2 - 56 × 3/8 inch STAINLESS panhead machine screw
# 2 steel flat washer
# 2 steel internal tooth lockwasher
# 2 STAINLESS STEEL hex. machine nut
ADS# 4-7-6
ADS# 4-5-18
ADS# 3-18- 88
ADS# 3-18-113
ADS# 3-18-189
ADS# 12-18-32
ADS# 12-18-42
ADS# 12-18-43
ADS# 12-18-44
ADS# 3-27-22
ADS# 12-6-28
ADS# 12-3-50
ADS# 12-7-7
TOKO
PULSE
ADI# AD8323XRU
DCS
ADS# 30-1-1
ADS# 30-16-3
ADS# 30-1-17
ADS# 30-6-6
ADS# 30-5-2
ADS# 30-7-6
C18
C1–8, 10–13
R1–3, 8, 11, 12
R6
R5
TP13, 14
TP1–6, 16–19
TP15
TP20
JP1–3
VIN+, VIN–, HPP, CABLE
P1
VCC, GND
T2 B
U2
U1
Evaluation PC Board
DO NOT INSTALL C14–C17, R4, R7, R9, T1, T2A, TP7–TP12, TP21, TP22.
*PULSE Diplexer part #’s B5008 (42 MHz), CX6002 (42 MHz), B5009 (65 MHz).
REV. 0
–15–
(p1 hardware)
(p1 hardware)
(p1 hardware)
(p1 hardware)
AD8323
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
C02045–2.5–7/00 (Rev. 0)
28-Lead TSSOP
(RU-28)
0.386 (9.80)
0.378 (9.60)
28
15
0.177 (4.50)
0.169 (4.30)
0.256 (6.50)
0.246 (6.25)
1
14
PIN 1
SEATING
PLANE
0.0433 (1.10)
MAX
0.0256 (0.65) 0.0118 (0.30)
BSC
0.0075 (0.19)
0.0079 (0.20)
0.0035 (0.090)
8ⴗ
0ⴗ
0.028 (0.70)
0.020 (0.50)
PRINTED IN U.S.A.
0.006 (0.15)
0.002 (0.05)
–16–
REV. 0