BB AFE1115E

®
AFE
111
AFE1115
®
5
HDSL/MDSL ANALOG FRONT END WITH VCXO
● +5V ONLY (5V or 3.3V Digital)
● SCALEABLE DATA RATE
● 300mW POWER DISSIPATION
FEATURES
● COMPLETE HDSL ANALOG INTERFACE
● E1, T1 AND MDSL OPERATION
● 56-PIN SSOP
● VCXO AND VCXO CONTROL CIRCUITRY
DESCRIPTION
Burr-Brown’s Analog Front End greatly reduces the
size and cost of an HDSL (High bit rate Digital
Subscriber Line) system by providing all of the active
analog circuitry needed to connect an HDSL digital
signal processor to an external compromise hybrid and
a HDSL line transformer. The transmit and receive
filter responses automatically change with clock frequency—allowing the AFE1115 to operate over a
range of data rates from 196kbps to 1.168Mbps.
Functionally, this unit consists of a transmit and a
receive section with a VCXO (Voltage Controlled
Crystal Oscillator) control DAC and VCXO circuitry.
The transmit section generates, filters, and buffers
outgoing 2B1Q data. The receive section filters and
digitizes the symbol data received on the telephone
line. Data to the VCXO and symbol data are sent to the
AFE1115 via two serial interfaces; the receive data is
available as a 14-bit parallel word. This IC operates on
a single 5V supply. The digital circuitry in the unit can
be connected to a supply from 3.3V to 5V. It is housed
in a small 56-pin SSOP package.
vcDATA
vcDAC
VCXO
DAC
vcSCLK
VCXO Output
vcLE
Oscillator
VCXO Input
VCXO Output Clock
Pulse
Former
Filter
Output
Buffer
txLINE+
txLINE–
REFP
PLLOUT
PLLIN
Voltage
Reference
Transmit
Control
txDATA+
VCM
REFN
txSCLK
txCLK
rxSYNC
Receive
Control
rxLOOP
rxLINE+
2
rxGAIN
Delta-Sigma
Modulator
14
rxDATA
rxLINE–
rxHYB+
rxHYB–
Decimation
Filter
International Airport Industrial Park • Mailing Address: PO Box 11400, Tucson, AZ 85734 • Street Address: 6730 S. Tucson Blvd., Tucson, AZ 85706 • Tel: (520) 746-1111 • Twx: 910-952-1111
Internet: http://www.burr-brown.com/ • FAXLine: (800) 548-6133 (US/Canada Only) • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132
®
©
1997 Burr-Brown Corporation
PDS-1384
1
AFE1115
Printed in U.S.A. July, 1997
SPECIFICATIONS
Typical at 25°C, AVDD = +5V, DVDD = +3.3V, ftx = 584kHz (E1 rate), unless otherwise specified.
AFE1115E
PARAMETER
RECEIVE CHANNEL
Number of Inputs
Input Voltage Range
Common-Mode Voltage
Input Impedance All Inputs
Input Capacitance
Input Gain Matching
Resolution
Programmable Gain
Settling Time for Gain Change
Gain + Offset Error
Output Data Coding
Output Data Rate, rxSYNC(3)
TRANSMIT CHANNEL
Transmit Clock Rate, ftx
T1 Transmit –3dB Point
T1 Rate Power(4, 5)
E1 Transmit –3dB Point
E1 Transmit Power(4, 5)
Pulse Output
Common-Mode Voltage, VCM
Output Resistance(6)
TRANSCEIVER PERFORMANCE
Uncancelled Echo(7)
VCXO
VCXO
VCXO
VCXO
VCXO
PERFORMANCE
Control DAC Resolution
Control DAC Output
Control DAC Output
Performance
DIGITAL INTERFACE(6)
Logic Levels
VIH
VIL
VOH
VOL
POWER
Analog Power Supply Voltage
Analog Power Supply Voltage
Digital Power Supply Voltage
Digital Power Supply Voltage
Power Dissipation(4, 5, 8)
Power Dissipation(4, 5, 8)
PSRR
COMMENTS
MIN
Differential
Balanced Differential(1)
2
Line Input vs Hybrid Input
Three Gains: –3dB, 3dB, and 9dB
Tested at Each Gain Range
Two’s Complement
TYP
±3.0
+2.5
See Typical Performance Curves
10
±2
14
–3
+9
6
5
98
Symbol Rate
Bellcore TA-NWT-3017 Compliant
See Test Method Section
ETSI RTR/TM-03036 Compliant
See Test Method Section
DC to 1MHz
MAX
98
584
kHz
kHz
dBm
kHz
dBm
14
13
14
See Typical Performance Curves
AVDD/2
1
–67
–67
–71
–73
8
Positive Full Scale Output
Negative Full Scale Output
See VCXO Circuit and Layout Section
|IIH| < 10µA
|IIL| < 10µA
IOH = –20µA
IOL = 20µA
DVDD +0.3
+0.8
+0.4
Specification
Operating Range
Specification
Operating Range
AVDD = 5V, DVDD = 3.3V,
AVDD = DVDD = 5V
TEMPERATURE RANGE
Operating(6)
5
4.75
V
V
V
V
5.25
+85
°C
3.3
300
350
60
–40
dB
dB
dB
dB
V
V
V
V
mW
mW
dB
5.25
3.15
V
Ω
Bits
V
V
4.5
0.5
DVDD –1
–0.3
DVDD –0.5
pF
%
Bits
dB
Symbol Periods
%FSR(2)
kHz
292
rxGAIN = –3dB, Loopback Enabled
rxGAIN = –3dB, Loopback Disabled
rxGAIN = 3dB, Loopback Disabled
rxGAIN = 9dB, Loopback Disabled
V
V
584
196
13
UNITS
NOTES: (1) With a balanced differential signal, the positive input is 180° out of phase with the negative input, therefore the actual voltage swing about the commonmode voltage on each pin is ±1.5V to achieve a total input range of ±3.0V or 6Vp-p. (2) FSR is Full-Scale Range. (3) The output data is available at twice the symbol
rate with interpolated values. (4) With a pseudo-random equiprobable sequence of HDSL pulses; 13.5dBm applied to the transformer (16.5dBm output from txLINEP
and txLINEN). (5) See the Test Method section of this data sheet for more information. (6) Guaranteed by design and characterization. (7) Uncancelled Echo is a
measure of the total analog errors in the transmitter and receiver sections including the effect of non-linearity and noise. See the Discussion of Specifications sections
of this data sheet for more information. (8) Power dissipation includes only the power dissipated with in the component and does not include power dissipated in the
external loads. See the Discussion of Specifications section for more information.
®
AFE1115
2
PIN CONFIGURATION
PACKAGE/ORDERING INFORMATION
vcOUT
1
56
DGND
vcINP
2
55
vcSCLK
vcCLK
3
54
vcDATA
DVDD
4
53
vcLATCH
Unused Pin
5
52
PLLIN
Unused Pin
6
51
PLLOUT
txCLK
7
50
AVDD
txSCLK
8
49
AGND
txDATA
9
48
AGND
rxDATA0
10
47
vcDAC
rxDATA1
11
46
AGND
rxDATA2
12
45
txLINE+
rxDATA3
13
44
AVDD
rxDATA4
14
43
txLINE–
rxDATA5
15
42
AGND
GNDD
16
41
AVDD
AFE1115E
DVDD
17
40
vrREF
rxDATA6
18
39
VCM
rxDATA7
19
38
vrREF
rxDATA8
20
37
AGND
rxDATA9
21
36
AGND
rxDATA10
22
35
rxLINE+
rxDATA11
23
34
rxLINE–
rxDATA12
24
33
rxHYB+
rxDATA13
25
32
rxHYB–
Unused Pin
26
31
AVDD
rxSYNC
27
30
rxLOOP
rxGAIN0
28
29
rxGAIN1
PRODUCT
PACKAGE
PACKAGE
DRAWING
NUMBER(1)
AFE1115E
56-Pin Plastic SSOP
346
TEMPERATURE
RANGE
–40°C to +85°C
NOTE: (1) For detailed drawing and dimension table, please see end of data
sheet, or Appendix C of Burr-Brown IC Data Book.
ELECTROSTATIC
DISCHARGE SENSITIVITY
This integrated circuit can be damaged by ESD. Burr-Brown
recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling
and installation procedures can cause damage.
ESD damage can range from subtle performance degradation
to complete device failure. Precision integrated circuits may
be more susceptible to damage because very small parametric
changes could cause the device not to meet its published
specifications.
®
3
AFE1115
PIN DESCRIPTIONS
PIN #
TYPE
NAME
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
Output
Input
Output
Power
NC
NC
Input
Input
Input
Output
Output
Output
Output
Output
Output
Ground
Power
Output
Output
Output
Output
Output
Output
Output
Output
NC
Input
Input
Input
Input
Power
Input
Input
Input
Input
Ground
Ground
Output
Output
Output
Power
Ground
Output
Power
Output
Ground
Output
Ground
Ground
Power
Output
Input
Input
Input
Input
Ground
vcOUT
vcINP
vcCLK
DVDD
Unused Pin
Unused Pin
txCLK
txSCLK
txDATA
rxDATA0
rxDATA1
rxDATA2
rxDATA3
rxDATA4
rxDATA5
GNDD
DVDD
rxDATA6
rxDATA7
rxDATA8
rxDATA9
rxDATA10
rxDATA11
rxDATA12
rxDATA13
Unused Pin
rxSYNC
rxGAIN0
rxGAIN1
rxLOOP
AVDD
rxHYB–
rxHYB+
rxLINE–
rxLINE+
AGND
AGND
vrREFP
VCM
vrREFN
AVDD
AGND
txLINE–
AVDD
txLINE+
AGND
vcDAC
AGND
AGND
AVDD
PLLOUT
PLLIN
vcLATCH
vcDATA
vcSCLK
DGND
DESCRIPTION
VCXO Output
VCXO Input
VCXO Output Clock
Digital Supply (+3.3 to +5V)
Transmit Baud Clock (XMTLE signal) (1168kHz for E1)
Transmit Serial Clock
Transmit Data Input
ADC Output Bit-0
ADC Output Bit-1
ADC Output Bit-2
ADC Output Bit-3
ADC Output Bit-4
ADC Output Bit-5
Digital Ground
Digital Supply (+3.3 to +5V)
ADC Output Bit-6
ADC Output Bit-7
ADC Output Bit-8
ADC Output Bit-9
ADC Output Bit-10
ADC Output Bit-11
ADC Output Bit-12
ADC Output Bit-13
(DVDD may be connected for pinout compatibility with AFE1105)
ADC Sync Signal (392kHz for T1, 584kHz for E1)
Receive Gain Control Bit-0
Receive Gain Control Bit-1
Loopback Control Signal (loopback is enabled by positive signal)
Analog Supply (+5V)
Negative Input from Hybrid Network
Positive Input from Hybrid Network
Negative Line Input
Positive Line Input
Analog Ground
Analog Ground
Positive Reference Output
Common-mode Voltage (buffered)
Negative Reference Output
Analog Supply (+5V)
Analog Ground
Negative Line Output
Analog Supply (+5V)
Positive Line Output
Analog Ground
VCXO Control
Analog Ground
PLL Ground
PLL Supply
PLL Filter Output
PLL Filter Input
VCXO Control Latch Enable
VCXO Control Data
VCXO Control Serial Clock
Digital Ground
The information provided herein is believed to be reliable; however, BURR-BROWN assumes no responsibility for inaccuracies or omissions. BURR-BROWN
assumes no responsibility for the use of this information, and all use of such information shall be entirely at the user’s own risk. Prices and specifications are subject
to change without notice. No patent rights or licenses to any of the circuits described herein are implied or granted to any third party. BURR-BROWN does not
authorize or warrant any BURR-BROWN product for use in life support devices and/or systems.
®
AFE1115
4
TYPICAL PERFORMANCE CURVES
At Output of Pulse Transformer
The curves shown below are measured at the line output of the HDSL transformer. Typical at 25°C, AVDD = +5V, DVDD = +3.3V, unless otherwise specified.
POWER SPECTRAL DENSITY LIMIT
Power Spectral Density (dBm/Hz)
–20
–38dBm/Hz for T1
–40
–80dB/decade
T1
–40dBm/Hz for E1
E1
–60
–80
196kHz
292kHz
–118dBm/Hz
for T1
–120dBm/Hz
for E1
–100
–120
1K
10K
1M
100K
10M
Frequency (Hz)
CURVE 1. Upper Bound of Power Spectral Density Measured at Output of HDSL Transformer.
0.4T 0.4T
B = 1.07
C = 1.00
D = 0.93
QUATERNARY SYMBOLS
NORMALIZED
LEVEL
A
B
C
D
E
F
G
H
0.01
1.07
1.00
0.93
0.03
–0.01
–0.16
–0.05
+3
+1
–1
–3
0.0264
2.8248
2.6400
2.4552
0.0792
–0.0264
–0.4224
–0.1320
0.0088
0.9416
0.8800
0.8184
0.0264
–0.0088
–0.1408
–0.0440
–0.0088
–0.9416
–0.8800
–0.8184
–0.0264
0.0088
0.1408
0.0440
–0.0264
–2.8248
–2.6400
–2.4552
–0.0792
0.0264
0.4224
0.1320
DON'T DELETE TABLE
UNTIL KNOWN IF TEEPLE IS LEAVING IT IN?
1.25T
A = 0.01
E = 0.03
F = –0.01
–1.2T
–0.6T
A = 0.01
H = –0.05
14T
G = –0.16
0.5T
F = –0.01
50T
CURVE 2. Transmitted Pulse Template and Actual Performance as Measured at Transformer Output.
INPUT IMPEDANCE vs BIT RATE
Input Impedance (kΩ)
200
150
100
T1 = 784kbps,
45kΩ
50
E1 = 1168kbps,
30kΩ
0
100
300
700
500
900
1100
1300
Bit Rate (kbps)
CURVE 3. Input Impedance of rxLINE and rxHYB.
®
5
AFE1115
THEORY OF OPERATION
in remote units for clock recovery. The VCXO is formed
with the on-board circuitry plus external crystal and varactor
diodes. The VCXO control DAC receives control data through
a serial interface which sets a voltage level at the output of
the DAC. The DAC output controls the frequency of the
VCXO. To achieve specified analog performance when
using the VCXO, the crystal frequency of the VCXO must
be 48x the baud rate.
The transmit channel consists of a switched-capacitor pulse
forming network followed by a differential line driver. The
pulse forming network receives symbol data through a serial
interface and generates a standard 2B1Q output waveform.
The output meets the pulse mask and power spectral density
requirements defined in European Telecommunications Standards Institute document RTR/TM-03036 for E1 mode and
in sections 6.2.1 and 6.2.2.1 of Bellcore technical advisory
TA-NWT-001210 for T1 mode. The differential line driver
uses a composite output stage combining class B operation
(for high efficiency driving large signals) with class AB
operation (to minimize crossover distortion).
rxLOOP INPUT
rxLOOP is the loopback control signal. When enabled, the
rxLINE+ and rxLINE– inputs are disconnected from the
AFE. The rxHYB+ and rxHYB– inputs remain connected.
Loopback is enabled by applying a positive signal (Logic 1)
to rxLOOP.
The receive channel is designed around a fourth-order delta
sigma A/D converter. It includes a difference amplifier
designed to be used with an external compromise hybrid for
first order analog echo cancellation. A programmable gain
amplifier with gains of –3dB to +9dB is also included. The
delta sigma modulator operating at a 24X oversampling ratio
produces a parallel 14-bit output at symbol rates up to
584kHz. The basic functionality of the AFE1115 is illustrated in Figure 1 shown below.
The receive channel operates by summing the two differential inputs, one from the line (rxLINE) and the other from the
compromise hybrid (rxHYB). These two inputs are connected so that the hybrid signal is subtracted from the line
signal. This connection is described in the paragraph titled
“Echo Cancellation in the AFE”. The equivalent gain for
each input in the difference amp is one. The resulting signal
then passes to a programmable gain amplifier which can be
set for gains of –3dB through +9dB. The ADC converts the
signal to a 14-bit digital word, rxD13-rxD0.
ECHO CANCELLATION IN THE AFE
The rxHYB input is designed to be subtracted from the
rxLINE input for first order echo cancellation. To accomplish this, note that the rxLINE input is connected to the
same polarity signal at the transformer (positive to positive
and negative to negative) while the rxHYB input is connected to opposite polarity through the compromise hybrid
(negative to positive and positive to negative) as shown in
Figure 2.
RECEIVE DATA CODING
The data from the receive channel A/D converter is coded in
two’s complement.
ANALOG INPUT
OUTPUT CODE (rxDATA)
Positive Full Scale
Mid Scale
Negative Full Scale
An independent VCXO control DAC and VCXO circuitry is
also included on the chip. This VCXO is designed to be used
vcDATA
01111111111111
00000000000000
10000000000000
vcDAC
VCXO
DAC
vcSCLK
vcLE
VCXO Output
VCXO Input
VCXO
VCXO Output Clock
Transformer
Telephone
Wire Pair
Switched Capacitor
Pulse Former
Line Driver
Hybrid
PLL
DSP
∆Σ
ADC
Digital
Filter
Programmable
Gain Amp
Difference
Amplifier
AFE1115
FIGURE 1. Functional Block Diagram of AFE1115 Circuit.
®
AFE1115
6
0.1µF
txPLLOUT
REFP
VCM
0.1µF
0.1µF
REFN
1kΩ
txPLLIN
Parasitic Capacitance
Must be Minimized at
These Points.
200Ω
0.1µF
DVDD
68.1kΩ
VCXO Input, 2
BB809
150pF
68.1kΩ
VCXO Output, 1
1kΩ
150pF
68.1kΩ
vcDAC, 47
0.1µF
VCXO Output Clock, 3
1:2.3 Transformer
Tip
txLINEP
vcDATA
0.01µF
vcSCLK
txLINEN
vcLE
Ring
–
Input Antialias Filter
fc ≅ 2xSymbol Rate
txDAT
750Ω
txCLK
+
0.01µF
Compromise
Hybrid
–
+
rxHYB+
rxSYNC
rxGAIN
AFE1115
100pF
rxLOOP
rxG1
750Ω
rxD13
rxHYB–
750Ω
rxLINE–
PGND
DGND
AGND
100pF
AGND
750Ω
AGND
rxLINE+
AGND
AVDD
DVDD
AVDD
AVDD
AVDD
5V to 3.3V Digital
5V Analog
0.1µF
0.1µF
0.1µF 0.1µF
1 - 10µF
0.1µF
5 - 10Ω resistor may be
needed for isolation
FIGURE 2. Basic Connection Diagram.
rxHYB AND rxLINE INPUT ANTI-ALIASING FILTERS
An external input anti-aliasing filter is needed on the hybrid
and line inputs as shown in the Basic Connection Diagram
above. The –3dB frequency of the input anti-aliasing filter
for the rxLINE and rxHYB differential inputs should be
approximately 1MHz for E1 and T1 symbol rates. Suggested
values for the filter are 750Ω for each of the two input
resistors and 100pF for the capacitor. Together the two
750Ω resistors and the 100pF capacitor result in a 3dB
frequency of just over 1MHz. The 750Ω input resistors will
result in a minimal voltage divider loss with the input
impedance of the AFE1115.
For speed less than E1, the anti-aliasing filters will give best
performance with 3dB frequency approximately equal to
two times the symbol rate. For instance, a 3dB frequency of
400kHz may be used for a single line symbol rate of 196k
symbols per second.
RECEIVE CHANNEL PROGRAMMABLE
GAIN AMPLIFIER
The gain of the amplifier at the input of the Receive Channel
is set by two gain control pins, rxGAIN1 and rxGAIN0. The
resulting gain between –3dB and +9dB is shown below.
rxGAIN1
rxGAIN0
GAIN
0
0
–3dB
0
1
+3dB
1
0
+9dB
SCALEABLE DATA RATE
The AFE1115 scales operation with the clock frequency. All
internal filters and the pulse former change frequency with
the clock speed so that the unit can be used at different
frequencies just by changing the clock speed.
®
7
AFE1115
rxHYB AND rxLINE INPUT COMMON-MODE
OPTIONAL VOLTAGE
0.1µF
375Ω
The AFE1115 will meet specifications with the application
circuit shown in the Basic Connection Diagram (Figure 2)
above. However, slightly improved performance may be
obtained with the Hybrid input (rxHYB) and the Line input
(rxLINE) set to a common mode voltage of 1.5V. The
negative reference output pin (vrREFN, pin 40) provides a
good 1.5V level to use to set the common-mode voltage.
The circuit shown in Figure 3 can be used to set the
common-mode voltage of the Line input to 1.5V.
A similar circuit can be used to set the Hybrid input to 1.5V.
Another option for the Hybrid input is to design the external
compromise hybrid so that the signal into the rsHYB inputs
is centered at 1.5V. If the compromise hybrid circuit is AC
coupled to the rxHYB inputs, an external pull-up resistor to
vrREFN may be needed to center the input at 1.5V.
rxLINE–
2kΩ
AFE
to vrREFN
(1.5V)
100pF
to Line
2kΩ
0.1µF
375Ω
rxLINE+
FIGURE 3. Optional rxLINE Input Common-mode Voltage
Control.
TRANSMIT DATA TIMING
t1
txSCLK
(tx serial clock)
t2
t3
t4
t5
txCLK
(baud clock)
t6
txDATA
(tx data input)
MSB
Bit 1
t8
Bit 2
t7
LSB
Bit 16
Bit 3
t9
VCXO CONTROL TIMING
t1
vcSCLK
(serial clock)
t2
t3
t4
t5
vcLE
(latch enable)
t6
vcDATA
(data)
MSB
Bit 1
t8
SYMBOL
Bit 2
t7
LSB
Bit 16
Bit 3
t9
DESCRIPTION
MIN
TYP
MAX
UNITS
t1
Serial Clock Period
35
t2
Serial Clock LOW
15
ns
t3
Serial Clock HIGH
15
ns
t4
Delay of 16th clock rising edge to falling edge of txCLK or vcLE
10
ns
t5
Dealy of txCLK or vcLE to the next rising edge of Serial Clock
10
ns
t6
txCLK or vcLE HIGH
15
ns
t7
txCLK or vcLE LOW
15
ns
t8
DATA setup time
10
ns
t9
DATA hold time
10
ns
FIGURE 4. Timing Diagram.
®
AFE1115
8
ns
TRANSMIT SYMBOL DATA
During each symbol period transmit symbol data are sent to
the AFE1115 in serial format through the txDATA input pin.
A 16 bit word is sent to the AFE1115 to determine the
symbol that is transmitted by the AFE1115. The symbol data
is contained in the first three bits of the data, the remaining
13 bits of the 16 bit word are ignored.
The most significant bit (MSB) is the transmit enable bit.
When the MSB is a logic 0, a zero symbol only is transmitted regardless of the state of the other two bits. When the
MSB is a logic 1, bits 2 and 3 determine the symbol
transmitted as shown in the table below.
MSB - BIT 1
0
1
1
1
1
BIT 2
X
1
1
0
0
BIT 3
VCXO CONTROL D/A CONVERTER DATA
During each symbol period VCXO control D/A converter
data is sent to the AFE1115 in serial format through the
vcDATA input pin. A 16 bit word is sent to the AFE1115 to
determine the output of the VCXO control D/A converter.
The VCXO control D/A converter is connected to the
VCXO circuit to control the VCXO frequency. The D/A
converter input is contained in the first eight bits of the data,
the remaining eight bits of the 16 bit word are ignored.
2B1Q SYMBOL
X
1
0
1
0
O
+3
+1
–1
–3
INPUT CODE (vcDATA)
MSB
ANALOG OUTPUT
01111111XXXXXXXX
Negative Full Scale (+0.5V)
00000000XXXXXXXX
Mid Scale (+2.5V)
10000000XXXXXXXX
Positive Full Scale (+4.5V)
TABLE II. VCXO Control DAC Output. X = Don’t Care.
TABLE I. Transmit Symbol Data (txDATA). X = Don’t Care.
RECEIVE TIMING
t16
T = one symbol period
txCLK
t15
t10
rxSYNC
t11
t12
rxDATA
Data 1
Data 2
Data 1a
t14
t14
t14
t14
t13
NOTES: (1) rxSYNC can shift to one of 48 discrete delay times from the leading edge of txCLK. (2) Timing
is valid for load capacitance of 10pF or less. (3) It is recommended that rxDATA is read on the rising edge of
rxSYNC. (4) Data 1a is an interpolated value between Data 1 and Data 2.
FIGURE 5. Receive Timing Diagram.
PARAMETER
DESCRIPTION
MIN
t10
rxSYNC Pulse Width
T/24
TYP
MAX
t11
Delay of rxSYNC from rising edge of txCLK, n = 0 to 47
t12
Nominal Time at Which rxDATA Changes from Data 1 to Data 1a
(n + 1.5) T/48
t13
Nominal Time at Which rxDATA Changes from Data 1a to Data 2
(n + 25.5) T/48
t14
Uncertainty of t12 and t13
t15
txCLK Pulse Width
T/16
15T/16
t16
Symbol Period, T
1.7
10.2
nT/48 – T/96
VALUE
nT/48 + T/96
20
ns
µs
TABLE III. Receive Timing (n = Delay Increments from txCLK).
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9
AFE1115
RECEIVE TIMING
The rxSYNC signal controls portions of the A/D converter’s
decimation filter and the data output timing of the A/D
converter. It is generated at the symbol rate by the user and
must be synchronized with txCLK. The leading edge of
rxSYNC can occur at the leading edge of txCLK or it can be
shifted by the user in increments of 1/48 of a symbol period
to one of 47 discrete delay times after the leading edge of
txCLK.
The bandwidth of the A/D converter decimation filter is
equal to one half of the symbol rate. The A/D converter data
output rate is 2X the symbol rate. The specifications of the
AFE1115 assume that one A/D converter output is used per
symbol period and the other output is ignored. The Receive
Timing Diagram above suggests using the rxSYNC pulse to
read the first data output in a symbol period. Either data
output may be used. Both data outputs may be used for more
flexible post-processing.
Symbol sequences are generated by the tester and applied
both to the AFE and to the input of an adaptive filter. The
output of the adaptive filter is subtracted from the AFE
output to form the uncancelled echo signal. Once the filter
taps have converged, the RMS value of the uncancelled echo
is calculated. Since there is no far-end signal source or
additive line noise, the uncancelled echo contains only noise
and linearity errors generated in the transmitter and receiver.
The data sheet value for uncancelled echo is the ratio of the
RMS uncancelled echo (referred to the receiver input through
the receiver gain) to the nominal transmitted signal (13.5dBm
into 135Ω, or 1.74Vrms). This echo value is measured under
a variety of conditions: with loopback enabled (line input
disabled); with loopback disabled under all receiver gain
ranges; and with the line shorted (S1 closed in Figure 6).
POWER DISSIPATION
Approximately 75% of the power dissipation in the AFE1115
is in the analog circuitry, and this component does not
change with clock frequency. However, the power dissipation in the digital circuitry does decrease with lower clock
frequency. In addition, the power dissipation in the digital
section is decreased with operation from a smaller supply
voltage, such as 3.3V. (The analog supply, must remain in
the range 4.75V to 5.25V.)
DISCUSSION OF
SPECIFICATIONS
UNCANCELLED ECHO
The key measure of transceiver performance is uncancelled
echo. This measurement is made as shown in the diagram of
Figure 6 and the measurement is made as follows. The AFE
is connected to an output circuit including a typical 1:2.3
line transformer. The line is simulated by a 135Ω resistor.
The power dissipation listed in the specifications section
applies under these normal operating conditions: 5V Analog
Power Supply; 3.3V Digital Power Supply; E1 baud rate;
11.6Ω
Transmit
Data
txDATP
11.6Ω
txLINEN
1.5kΩ
rxHYBP
3kΩ
100pF
Adaptive
Filter
AFE1115
rxHYBN
1.5Ω
750Ω
rxLINEP
100pF
rxLINEN
750Ω
Uncancelled
Echo
rxD13 - rxD0
FIGURE 6. Uncancelled Echo Test Diagram.
®
AFE1115
1:2
5.6Ω
txLINEP
10
5.6Ω
135Ω
S1
sible. The placement of the Tantalum capacitor is not as
critical, but should be close to the pin. In each case, the
capacitor should be connected between AVDD and AGND
(pins 49 and 50). The capacitors should be placed in quiet
analog areas rather than noisy digital areas.
13.5dBm delivered to the line; and a pseudo-random
equiprobable sequence of HDSL pulses. The power dissipation specifications includes all power dissipated in the
AFE1115, it does not include power dissipated in the external
load.
The external power is 16.5dBm, 13.5dBm to the line and
13.5dBm to the impedance matching resistors. The external
load power of 16.5dBm is 45mW. The typical power dissipation in the AFE1115 under various conditions is shown in
BIT RATE
PER AFE1115
(Symbols/sec)
DVDD
(V)
TYPICAL POWER
DISSIPATION
IN THE AFE1115
(mW)
1168 (E1)
1168 (E1)
784 (T1)
784 (T1)
292 (1/4 E1)
292 (1/4 E1)
3.3
5
3.3
5
3.3
5
300
350
290
330
280
300
In most systems, it will be natural to derive AVDD for the
phase-locked loop (PLL) from the AVDD supply. A 5Ω to
10Ω resistor should be used to connect PLL AVDD (pin 49)
to the analog supply. This resistor in combination with the
10µF capacitor form a lowpass filter—keeping glitches on
the analog supply from affecting the phase locked loop.
Ideally, the phase-locked loop power supply would originate
from the analog supply (via the 5Ω to 10Ω resistor) near the
power connector for the printed circuit board. Likewise, the
PLL ground should connect to a large PCB trace or small
ground plane which returns to the power supply connector
underneath the PLL AVDD supply path. The PLL “ground
plane” should also extend underneath PLLIN and PLLOUT
(pins 51 and 52).
TABLE IV. Typical Power Dissipation.
The remaining portion of the AFE1115 should be considered
analog. The four non-PLL AGND pins (pins 36, 37, 42, and
46) should be connected directly to a common analog
ground plane and all non-PLL AVDD pins should be connected to an analog 5V power plane. Both of these planes
should have a low impedance path to the power supply.
Table IV.
LAYOUT
The analog front end of an HDSL system has a number of
conflicting requirements. It must accept and deliver digital
outputs at fairly high rates of speed, generate a VCXO clock,
phase-lock to a high-speed digital clock, and convert the line
input to a high-precision (14-bit) digital output. Thus, there
are really four sections of the AFE1115: the digital section,
the phase-locked loop, the VCXO and the analog section.
Ideally, all ground planes and traces and all power planes
and traces should return to the power supply connector
before being connected together (if necessary). Each ground
and power pair should be routed over each other, should not
overlap any portion of another pair, and the pairs should be
separated by a distance of at least 0.25 inch (6mm). One
exception is that the digital and analog ground planes should
be connected together underneath the AFE1115 by a small
trace.
DIGITAL LAYOUT
The power supply for the digital section of the AFE1115 can
range from 3.3V to 5V. This supply should be decoupled to
digital ground with a ceramic 0.1µF capacitor placed as
close as possible to digital ground (DGND, pin 16) and
digital power (DVDD, pin 17). Ideally, both a digital power
supply plane and a digital ground plane should run to and
underneath the digital pins of the AFE1115 (pins 7 through
30). However, DVDD may be supplied by a wide printed
circuit board trance. A digital ground plane underneath all
digital pins is strongly recommended. The VCXO circuit
needs special attention for layout. There is a portion of the
external VCXO circuitry which needs to be as far away as
possible from a ground or power plane or other traces. See
the discussion below in the section titled VCXO Circuit and
Layout.
VCXO CIRCUIT AND LAYOUT
The VCXO circuitry is shown in Figure 7. The basic VCXO
circuit consists of on-chip control DAC, amplifiers, Schmidt
triggers, and clock buffer along with an external crystal and
varactor diodes. The control DAC output (vcDAC) varies
the capacitance of the varactor diodes (D1 and D2), which
controls the frequency at which the crystal circuit oscillates.
The buffered clock output is available at pin 3, VCXO Clock
Output.
Important Note: To achieve specified analog performance
when using VCXO, the crystal frequency of the VCXO must
be 48x the baud rate. In addition, the txCLK and the
rxSYNC control signals must be derived from the VCXO
clock so that the edges of the control signal are synchronized
with the 48x crystal frequency. If these recommendations
are followed, the key internal analog decisions are made at
the time of minimum noise. As an example, for an E1 rate
of 1168kbps, the symbol rate is 584k symbols per second. In
this case the VCXO crystal frequency should be 48 x 584k
= 28.032MHz. Likewise, for T1, the crystal frequency should
be 18.816MHz.
ANALOG LAYOUT
The phase-locked loop is powered from AVDD (pin 50) and
its ground is referenced to AGND (pin 49). Note that AVDD
must be in the 4.75V to 5.25V range. This portion of the
AFE1115 should be decoupled with both 10µF Tantalum
capacitor and a 0.1µF ceramic capacitor. The ceramic capacitor should be placed as close to the AFE1115 as pos-
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11
AFE1115
Figure 8 shows an example of a printed circuit board layout
of the sensitive VCXO circuitry for the circuit shown in
Figure 7. There should be no ground planes, power planes or
other traces in the white area indicated around the two
sensitive points. The balance of the circuit board should be
covered by ground planes where possible. With the circuit
shown in Figure 7, these typical specifications were achieved.
The performance of the VCXO is critically dependent on the
external components and printed circuit board layout that is
used. The varactor diodes and the crystal are particularly
important components.
The printed circuit board layout containing the two varactor
diodes, D1 and D2, in the VCXO external circuitry is critical
to the performance of the VCXO. In particular, the two
connection points of the varactor diodes shown in the Figure
7 must have very low parasitic capacitance to ground to
achieve the best tuning range possible. To achieve lowest
parasitic capacitance to ground, there must be no ground
plane or other PCB traces near these two points. Ground
planes and other traces should be kept 1 cm away from these
two points where possible.
±125ppm
Pull Range at 20MHz
Frequency Range of Crystal that can be used
Crystal Frequency
Parasitic capacitance must be minimized
at these points. No other traces or ground
plane should be inside the dotted box.
48x baud rate
AFE1115
DVDD
68.1kΩ
R2
D2
VCXO Input, 2
D1
150pF
VCXO Output, 1
68.1kΩ
R4
68.1kΩ
150pF
R5
RL
vcDAC, 47
0.1µF
Buffered VCXO Clock Output
RL = 1kΩ for 5V Operation
RL = 600Ω for 3.3V Operation
D1 = D2 = Philips Semiconductor BB809
VCXO Clock Output, 3
FIGURE 7. VCXO Circuitry.
To AFE1115 Pin #47
XTAL
68.1k
Ground
Plane
Sensitive Points
68.1k
No ground/power planes
or other traces in this area
To AFE1115 Pin #2
FIGURE 8. VCXO Circuit Layout, Approximately Two Times Actual Size.
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AFE1115
12
10MHz to 28MHz