EXAR XRT71D00IQ

XRT71D00
E3/DS3/STS-1 JITTER ATTENUATOR,STS-1 TO DS3 DESYNCHRONIZER
JULY 2000
REV. 1.01
GENERAL DESCRIPTION
The XRT71D00 is a single channel, single chip Jitter
Attenuator, that meets the Jitter requirements specified in the ETSI TBR-24, Bellcore GR-499 and GR253 standards.
In addition, the XRT71D00 also meets the Jitter and
Wander specifications described in the ANSI
T1.105.03b 1997, Bellcore GR-253 and GR-499 standards for Desynchronizing and Pointer adjustments in
the DS3 to STS-SPE mapping applications.
• Meets output jitter requirement as specified by
ETSI TBR24
• Meets the Jitter and Wander specifications
described in T1.105.03b,GR-253 and GR-499 standards.
• Selectable buffer size of 16 and 32 bits
• Jitter attenuator can be disabled
• Available in a 32 pin TQFP package.
• Single 3.3V or 5.0V supply.
• Operates over - 400 C to 850 C temperature range.
FEATURES
• Meets the E3/DS3/STS-1 jitter requirements
APPLICATIONS
• E3/DS3 Access Equipment.
• No external components required
• Compliance with jitter transfer template outlined in
ITU G.751, G.752, G.755 and GR-499-CORE,1995
standards
• STS-SPE to DS3 Mapper
• DSLAMs
BLOCK DIAGRAM OF THE XRT71D00
BW S
M C lk
T im in g C on tro l B lo c k /
P h a s e lo c k ed L oo p
IC T
DJA
R C lk
W rite C lock
R ead C lock
R R C lk
RRPO S
C lk E S
RPOS
RNEG
1 6 /3 2 B it F IF O
RRNEG
FL
H O S T/H W
RST
M ic ro p ro c es s o r S e ria l
In te rfa ce
D S 3/E 3
CS SDI
SDO
S C lk
Exar Corporation 48720 Kato Road, Fremont CA, 94538 • (510) 668-7000 • FAX (510) 668-7017 • www.exar.com
E3/DS3/STS-1 JITTER ATTENUATOR,STS-1 TO DS3 DESYNCHRONIZER
XRT71D00
REV. 1.01
32
NC
NC
R R P OS
VDD
C h_ A ddr_0
E3 / DS3 / CS
VDD
R P OS
NC
PIN OUT OF THE XRT71D00 (32 LEAD TFQP PACKAGE)
25
24
1
RNEG
NC
RRNEG
R C lk
R R C lk
GND
GND
M C lk
IC T
GND
RST
VDD
17
B W S /C h_A d dr_ 1
FL
NC
H O ST/H W
FS S /S C lk
16
C lkE S /S D I
NC
9
NC
NC
S TS -1
D JA /S D O
8
ORDERING INFORMATION
PART NUMBER
PACKAGE
OPERATING TEMPERATURE RANGE
XRT71D00IQ
32 Lead TQFP
-400C to +850C
2
XRT71D00
E3/DS3/STS-1 JITTER ATTENUATOR, STS-1 TO DS3 DESYNCHRONIZER
PRELIMINARY
REV. 1.01
GENERAL DESCRIPTION ................................................................................................. 1
FEATURES ....................................................................................................................................................
APPLICATIONS ..............................................................................................................................................
BLOCK DIAGRAM OF THE XRT71D00 ............................................................................................................
PIN OUT OF THE XRT71D00 (32 LEAD TFQP PACKAGE) ..............................................................................
ORDERING INFORMATION ...............................................................................................
PIN DESCRIPTIONS ..........................................................................................................
ELECTRICAL CHARACTERISTICS ..................................................................................
SYSTEM DESCRIPTION ....................................................................................................
1
1
1
2
2
3
6
8
Figure 1. Illustration of the XRT71D00 ( configured to operate in the “Hardware” Mode) .....................8
Figure 2. Illustration of the XRT71D00(configured to operate in the “Host” Mode) ................................. 9
BACKGROUND INFORMATION: ........................................................................................................................ 9
Figure 3. Category 1 DS3 Jitter Transfer Mask ..........................................................................................10
JITTER ATTENUATION: .......................................................................................................................... 10
Figure 4. XRT71D00 Desynchronizer Block Diagram ................................................................................ 11
TABLE 1: FUNCTIONS OF DUAL MODE PINS IN “HARDWARE” MODE CONFIGURATION ......................................... 11
TABLE 2: ADDRESS AND BIT FORMATS OF THE COMMAND REGISTERS ............................................................. 12
Figure 5. Microprocessor Serial Interface Data Structure .........................................................................13
Figure 6. Timing Diagram for the Microprocessor Serial Interface .......................................................... 13
Figure 7. Input/Output Timing ......................................................................................................................14
TABLE 3: XRT71D00 J ITTER TRANSFER FUNCTION ......................................................................................... 14
TABLE 4: XRT71D00 MAXIMUM JITTER TOLERANCE ........................................................................................ 15
PACKAGE INFORMATION .............................................................................................. 16
32 LEAD TQFP PACKAGE DIMENSIONS ....................................................................................... 16
ORDERING INFORMATION ............................................................................................................. 16
REVISIONS ....................................................................................................................... 17
III
E3/DS3/STS-1 JITTER ATTENUATOR, STS-1 TO DS3 DESYNCHRONIZER
XRT71D00
REV. 1.01
PIN DESCRIPTIONS
PIN DESCRIPTION
PIN #
NAME
TYPE
1
NC
***
2
RNEG
I
DESCRIPTION
This pin is not connected internally
Receive Negative Data (Jittery)
The input jittery negative data is sampled either on the rising or falling
edge of RClk depending on the setting of ClkES (pin 10).
If ClkES is “high”, then RNEG will be sampled on the falling edge of RClk.
If ClkES is “low”, then RPOS will be sampled on the rising edge of RClk.
This pin is typically tied to the “RNEG” output pin of the LIU.
3
RClk
I
Receive Clock (Jittery)
Clock input RClk should be connected to the recovered clock.
4
GND
***
5
MClk
I
Digital Ground
Master Clock Input.
Reference clock for internal PLL. 44.736MHz+/-20ppm or 34.368MHz+/20ppm. This clock must be continuous and jitter free with duty cycle
between 30 to 70%.
NOTE: It is permissible to use the EXClk signal orSTS-1 clock.
6
GND
***
Analog Ground
7
VDD
***
Analog Positive Supply: 3.3V or 5.0V ± 5%
8
STS-1
I
SONET STS-1 Mode Select:
This pin along with the E3/DS3* select pin (pin 29) configures the
XRT71D00 either in E3, DS3 or STS-1 mode.
A table relating to the setting of the pins is given below:
STS-1
E3/DS3*
XRT71D00 Operating Mode
0
0
DS3 (44.736 MHz)
0
1
E3 (34.368 MHz)
1
0
STS-1 (51.84 MHz)
1
1
E3 (34.368 MHz)
NOTES:
1. This input pin is active only in the Hardware Mode
2. Internal 50 K Ohm pull-up resistor.
9
NC
***
10
ClkES/(SDI)
I
This pin is not connected internally
Clock Edge Select Input/Serial Data Input Pin.
The function of this pin depends on whether XRT71D00 is configured in
Harware or Host Mode.
Hardware Mode—Clock Edge Select Input
The status of this pin determines the sampling edge on RClk to RPOS/
RNEG and RRPOS/RRNEG data update on RRClk edge.
When high: RPOS/RNEG is sampled on falling edge of RClk and
RRPOS/RRNEG is updated on rising edge of RRClk.
When low: RPOS/RNEG is sampled on rising edge of RClk and
RRPOS/RRNEG is updated on falling edge of RRClk.
Host Mode—Serial Data Input
The address value (of the command registers) or the data value is either
Read or Written through this pin.
The input data will be sampled on the rising edge of the SClk pin (pin 11).
4
XRT71D00
E3/DS3/STS-1 JITTER ATTENUATOR, STS-1 TO DS3 DESYNCHRONIZER
REV. 1.01
PIN DESCRIPTION
PIN #
NAME
TYPE
11
FSS/(SClk)
I
DESCRIPTION
FIFO Size Select Input/Serial Clock Input.
The function of this depends on whether XRT71D00 is configured in Hardware or Host mode.
Hardware Mode—FIFO Size Select Input
When high: Selects 32 bits FIFO.
When low: Selects 16 bits FIFO.
Host Mode—Microprocessor Serial Interface Clock Signal
This signal will be used to (1) sample the data, on the SDI pin, on the rising
edge of this signal. Additionally, during “Read” operations, the Microprocessor Serial Interface will update the SDO output on the falling edge of
this signal.
12
HOST/HW
I
Host/Hardware Mode Select:
An active-high input enables the Host mode. Data is written to the command registers to configure the XRT71D00.
In the Host mode, the states of discrete input pins are inactive.
An active-low input enables the Hardware Mode.In this mode, the discrete
inputs are active.
13
NC
***
14
FL
O
This pin is not connected internally.
FIFO Limit.
This output pin is driven high whenever the internal FIFO comes within
two-bits of being completely full.
15
BWS/
Ch_Addr_1
I
Bandwidth Select Input/Channel Addr_1 Assignment Input.
The function of this input pin depends on whether XRT71D00 is configured
in Host or Hardware mode.
Hardware Mode—Bandwidth Select Input:
Connect this pin high to select wide jitter transfer bandwidth, and connect
low to select narrow jitter transfer bandwidth.
Host Mode—Channel_Addr_1 Assignment Input:
This input pin, along with pin 28 permits the user to assign a “Channel
Address” to the XRT71D00 device.
16
NC
***
This pin is not connected internally.
17
NC
***
This pin is not connected internally.
18
DJA/
(SDO)
I/(O)
Disable Jitter Attenuator Input/Serial Data Output pin:
The function of this pin depends on whether XRT71D00 is configured in
Host or Hardware mode.
Hardware Mode—Disable Jitter Attenuator:
An active-high disables the Jitter Attenuator.The RPOS/RNEG and RClk
will be passed through without jitter attenuation.
Host Mode—Serial Data Output:
This pin will serially output the contents of the specified Command Register, during “Read” Operations. The data, on this pin, will be updated on the
falling edge of the SClk input signal. This pin will be tri-stated upon completion of data transfer.
NOTE: The user is advised to tie this pin to GND, if the XRT71D00 has
been configured to operate in the “HOST” Mode.
19
RST
I
Reset Input. (Active-Low)
A high-low transition will re-center the internal FIFO, and will clear the
Command Registers (for Host Mode operation). Resetting this pin may
corrupt data within the device.
For normal operation, pull this pin to VDD.
5
E3/DS3/STS-1 JITTER ATTENUATOR, STS-1 TO DS3 DESYNCHRONIZER
XRT71D00
REV. 1.01
PIN DESCRIPTION
PIN #
NAME
TYPE
DESCRIPTION
20
ICT
I
In Circuit Testing Input. Active low.
With this pin tied to ground, all output pins will be in high impedance mode
for in-circuit-testing.
For normal operation this input pin should be tied to VDD.
21
GND
***
Digital Ground:
22
RRClk
O
Receive Output (De-jittered) Clock.
Output the de-jittered or smoothed clock if the jitter attenuator is enabled.
The de-jittered data, RRPOS/RRNEG are clocked to this signal.
If ClkES is “low”, RRPOS/RRNEG will be updated at the falling edge of
RRClk.
If ClkES is “high”, RRPOS/RRNEG will be updated at the rising edge of
RRClk.
23
RRNEG
O
Receive Negative Data (De-Jittered) Output.
De-jittered negative data output. Updated on the rising or falling edge of
RRClk, depending upon the state of the ClkES input pin (or bit-field setting).
24
NC
***
This pin is not connected internally.
25
NC
***
This pin is not connected internally.
26
RRPOS
O
Receive Positive Data (De-Jittered) Output.
De-jittered positive data output. Updated on the rising or falling edge of
RRClk (see pin 9), depending upon the state of the ClkES input pin (or bitfield setting).
27
VDD
***
28
Ch_Addr_0
I
Digital Positive Supply Voltage: 3.3V or 5.0V ± 5%
Channel Addr_0 Assignment Input.
This input pin, along with pin 15 permits the user to assign a “Channel
Address” to the XRT71D00.
29
E3/DS3
(CS)
I
E3/DS3 Select Input/Chip Select Input:
The function of this pin depends on whether the XRT71D00 is configured
in Host or Hardware mode.
Hardware Mode—E3/DS3* Select Input:
This pin along with the STS-1 mode select pin (pin 8) selects the operating
mode. The following table provides the configuration:
STS-1
0
0
1
1
E3/DS3*
0
1
0
1
XRT71D00 Operating Mode
DS3 (44.736 MHz)
E3 (34.368 MHz)
STS-1 (51.84 MHz)
E3 (34.368 MHz)
HOST Mode—Chip Select Input:
An active-low input enables the serial interface. (Note: This pin is internally
pulled “high”.)
30
VDD
***
31
RPOS
I
Digital Positive Supply Voltage: 3.3V or 5.0V ± 5%
Receive Positive Data (Jittery) Input.
Data that is input on this pin is sampled on either the rising or falling edge
of RClk depending on the setting of the ClkES pin (pin 10).
If ClkES is “high”, then RPOS will be sampled on the falling edge of RClk.
If ClkES is “low”, then RPOS will be sampled on the rising edge of RClk.
32
NC
***
This pin is not connected internally.
6
XRT71D00
E3/DS3/STS-1 JITTER ATTENUATOR, STS-1 TO DS3 DESYNCHRONIZER
REV. 1.01
ELECTRICAL CHARACTERISTICS
AC Electrical Characteristics
SYMBOL
PARAMETER
MIN
TYP
MAX
UNITS.
30
50
70
%
MClk
Duty Cycle
MClk
Frequency E3
34.368
MClk
Frequency DS3
44.736
MHz
MClk
Frequency STS-1
51.84
MHz
RClk
Duty Cycle
RClk
Frequency
(E3,DS3 or STS-1)
MHz
30
50
70
%
-400
0
400
ppm
RClk
Rise Time
ns
RClk
Fall Time
ns
tsu
RPOS/RNEG to RClk rise time setup
5
ns
th
RPOS/RNEG to RClk rising hold time
5
ns
td
RRPOS/RRNEG delay from RRClk rising
5
ns
te
RRPOS/RRNEG delay from RRClk falling
5
ns
Microprocessor Serial Interface Timing ( see Figure 6)
SYMBOL
PARAMETER
MIN
TYP
MAX
UNITS.
t21
CSB Low to Rising Edge of SClk Setup Time
50
ns
t22
SClk to CSB Hold Time
20
ns
t23
SDI to Rising Edge of SClk Setup Time
50
ns
t24
SDI to Rising Edge of SClk Hold Time
50
ns
t25
SClk “Low” Time
240
ns
t26
SClk “High” Time
240
ns
t27
SClk Period
500
ns
t28
SClk to CSB Hold Time
50
ns
t29
CSB “Inactive” Time
250
ns
t30
Falling Edge of SClk to SDO Valid Time
t31
Falling Edge of SClk to SDO Invalid Time
t32
Falling Edge of SClk, or rising edge of CSB to High Z
7
100
200
ns
100
ns
ns
E3/DS3/STS-1 JITTER ATTENUATOR, STS-1 TO DS3 DESYNCHRONIZER
XRT71D00
REV. 1.01
DC Electrical Characteristics (TA = 25 0C, VDD = 3.3 V ± 5 % unless otherwise specified)
PARAMETER
SYMBOL
MIN
TYP
MAX
UNITS
Power Supply Voltage
VDD
3.135
3.3
3.465
V
Input High Voltage
VIH
2.0
5.25
V
Input Low Voltage
VIL
-0.5
0.8
V
Output High Voltage @ IOH=-5mA
VOH
2.4
Output Low Voltage @ IOL=5mA
VOL
Supply Current ( E3)
Icc
36
Supply Current ( DS3 )
Icc
40
Supply Current ( STS-1)
Icc
Input Leakage Current(except Input pins with Pull-up resistor.
IL
Input Capacitance
CI
Output Load Capacitance
CL
V
0.4
V
40
52
mA
41
43
mA
± 10
µA
TBD
5.0
pF
25
pF
DC Electrical Characteristics (TA = 25 0C, VDD = 5.0 V ± 5 % unless otherwise specified)
PARAMETER
SYMBOL
MIN
TYP
MAX
UNITS
Power Supply Voltage
VDD
4.75
5.0
5.25
V
Input High Voltage
VIH
2.0
5.25
V
Input Low Voltage
VIL
-0.5
0.8
V
Output High Voltage @ IOH=-5mA
VOH
2.4
Output Low Voltage @ IOL=5mA
VOL
Supply Current ( E3)
Icc
36
Supply Current ( DS3 )
Icc
40
Supply Current ( STS-1)
Icc
Input Leakage Current(except Input pins with Pull-up resistor.
IL
Input Capacitance
CI
Output Load Capacitance
CL
V
0.4
V
40
52
mA
41
43
mA
± 10
µA
TBD
5.0
25
ABSOLUTE MAXIMUM RATINGS:
Supply Range
-0.5 V to + 6.0 V
ESD Rating
> 2000 V on all pins
Operating Temperature
-400C to +850C
Storage Temperature
-65°C to + 150°C
8
pF
pF
XRT71D00
E3/DS3/STS-1 JITTER ATTENUATOR,STS-1 TO DS3 DESYNCHRONIER
REV. 1.01
SYSTEM DESCRIPTION
The XRT71D00 also meets the DS3 wander specification that apply to SONET and asynchronous interfaces as specified in the ANSI T1.105.03b 1997 standard.
The XRT71D00 is an integrated E3/DS3/STS-1 jitter
attenuator that attenuates the jitter from the input clock
and data.The jitter attenuation performance meets the
latest specifications such as Bellcore GR-499
CORE,GR-253 CORE, ETSI TBR24,ITU-T G.751,ITUT G.752 and ITU-T G.755 standards.
Additionally, to support loop-timing applications, the
XRT71D00 device can also be used to reduce and
limit the amount of jitter in the recovered line clock
signal.
In addition, the XRT71D00 also meets both the “mapping” and “pointer adjustment” jitter generation criteria for both Category I and Category II interfaces as
specified in Bellcore GR-253.
Figure 1 presents a simple block diagram of the
XRT71D00 device, when it is configured to operate in
the “Hardware” Mode and Figure 2 presents a simple
block diagram of the XRT71D00 device, when it is
configured to operate in the “Host” Mode.
FIGURE 1. ILLUSTRATION OF THE XRT71D00 ( CONFIGURED TO OPERATE IN THE “H ARDWARE” MODE)
BWS
ICT
Jittery
Clock
Timing Control Block /
Phase locked Loop
MClk
Smoothed
Clock
DJA
RClk
Write Clock
Read Clock
RRClk
RRPOS
ClkES
RPOS
RNEG
16/32 Bit FIFO
RRNEG
FL
FSS
HOST/HW
RST
DS3/E3
9
E3/DS3/STS-1 JITTER ATTENUATOR,STS-1 TO DS3 DESYNCHRONIER
XRT71D00
REV. 1.01
FIGURE 2. ILLUSTRATION OF THE XRT71D00(CONFIGURED TO OPERATE IN THE “HOST” MODE)
Jittery Clock
Timing Control Block /
Phase locked Loop
ICT
RClk
Write Clock
MClk
Smoothed
Clock
Read Clock
RRClk
RRPOS
16/32 Bit FIFO
RRNEG
RPOS
RNEG
HOST/HW
RST
FL
Microprocessor Serial
Interface
CS
SDI
SDO SClk
The XRT71D00 DS3/E3 Jitter Attenuator IC consists
of the following functional blocks:
3) Inter-symbol interference/Signal Distortion
• Timing Control Block
SONET equipment jitter criteria are specified as:
• The “Jitter-Attenuator” PLL
i) Jitter Transfer
• The “2-Channel 16/32 Bit FIFO”.
ii) Jitter Tolerance
BACKGROUND INFORMATION:
DEFINITION OF JITTER
iii) Jitter Generation
One of the most important and least understood measures of clock performance is jitter. The International
Telecommunication Union defines jitter as “short term
variations of the significant instants of a digita signal
from their ideal positions in time”. Jitter can occur due
to any of the following:
The primary purpose of jitter transfer requirements is
to prevent performance degradations by limiting the
accummulation of jitter through the system such that
it does not exceed the network interface jitter requirements. Thus, it is more important that a system meet
the jitter transfer criteria for relatively high input jitter
amplitudes. The jitter transferred through the system
must be under the jitter mask for any input jitter amplitude within the range as shown in Figure 3
SONET STS-1 to DS3 MAPPING
JITTER TRANSFER CHARACTERISTICS:
1) Imperfect timing recovery circuit in the system
2) Cross-talk noise
10
XRT71D00
E3/DS3/STS-1 JITTER ATTENUATOR,STS-1 TO DS3 DESYNCHRONIER
REV. 1.01
FIGURE 3. CATEGORY 1 DS3 JITTER TRANSFER MASK
Jitter Gain
(dB)
0.1
slope = -20 dB/decade
Acceptable
Range
40
Frequency (Hz)
JITTER TOLERANCE:
In Figure 1 and Figure 2, this “de-jittered” clock is labeled “Smoothed Clock”. This “Smoothed Clock” is
now used to “Read Out” the “Recovered Data” from
the 16/32 bit FIFO. This “Smoothed Clock” will also
be output to the Terminal Equipment via the “RRClk”
output pin. Likewise, the “Smoothed Recovered Data”
will output to the Terminal Equipment via the RRPOS
and RRNEG output pins.
The jitter tolerance in the network element is defined
as the maximum amount of jitter in the incoming signal that it can receive in an “error-free”manner.
JITTER GENERATION:
Jitter generation is defined in Section 7.3.3 of GR499-CORE. Jitter generation criteria exists for both
Category I and II interfaces, which consist of “mapping” and “pointer adjustment” jitter generation.
The XRT71D00 device is designed to work as a companion device with XRT7300 (STS-1/DS3/E3) Line
Interface Unit.
Mapping jitter is the sum of the intrinsic payload mapping jitter and the jitter that is generated as a result of
the bit stuffing mechnisms used in all of the asynchronous DSn mapping into STS SPE.
.ETSI TBR24 specifies the maximum output jitter in
loop timing must be no more than 0.4UIpp when measured between 100Hz to 800KHzwith upto 1.5UI input
jitter at 100Hz.. This means a jitter attenuator with
bandwidth less than 100Hz is required to be compliant with the standard. ITU G.751 is another application where low bandwidth jitter attenuator is needed
to smooth the gapped clock output in the de-multiplexer system.
JITTER ATTENUATION:
A digital Jitter Attenuation loop combined with the
FIFO provides Jitter attenuation. The Jitter Attenuator
requires no external components except for the reference clock.
Data is clocked into the FIFO with the associated
clock signal (TClk or RClk) and clocked out of the
FIFO with the dejittered clock and data. When the
FIFO is within 2 bits of being completely full, the FIFO
Limit (FL) will be set.
SONET STS-1 DS3 MAPPING:
Bellcore GR-253 section 3.4.2 and the ANSI T1.105199 describes the asynchronous mapping for DS3 into STS-1 SPE.
11
E3/DS3/STS-1 JITTER ATTENUATOR,STS-1 TO DS3 DESYNCHRONIER
XRT71D00
REV. 1.01
block diagram of the Desynchronizer is shown in
Figure 4.
An asynchronous mapping for DS3 into STS-1 SPE is
defined for clear-channel transport of DS3 signals
that meet the DSX-3 requirements in the GR-499CORE.
The elastic store accepts the STS-1 data stream and
a gapped clock. The gaps in the input clock inhibit the
elastic store from writing all but DS3 payload data.
When the input data has a rate lower than the output
data rate, the positive stuffing will occur. The stuffing
mechanism that generates the C-bits is implemented in a desynchronizer that has the jitter output less
than 0.4 UIpp assuming no jitter or wander at the input of the synchronizer and no pointer adjustments. A
The bit leaking circuit stores incoming STS-1 pointer
adjustments into a queue and leaks them out of the
desynchronizer one bit at a time.
STS-Nc signal is used to transport higher rate signals. However,the digital signals that SONET carries
do not fit in the SPE perfectly.
FIGURE 4. XRT71D00 DESYNCHRONIZER BLOCK DIAGRAM
S T S -1
re fe r e n ce c lo ck
S T S -N
C lo c k
S T S -N
XR T71D00
D S 3 p a ylo a d
(d e jitte re d )
S T S -1
S T S -1
OH
P ro c e s s in g
C lo c k
R e c o v e ry
S T S -1
g a p p e d c lo c k
D e s c ra m b le /
Dem ux
S T S -1
P o in te r
P ro c e s s in g
E la s tic
S to re
S e c tio n &
L in e O v e rh e a d
S T S -N
N th S T S -1
S T S -1
g a p p e d c lo c k
Hardware Mode
A listing of these Command Registers, their Addresses, and their bit-formats are listed below in Table 2.
TABLE 1: FUNCTIONS OF DUAL MODE PINS IN
“H ARDWARE” MODE CONFIGURATION
PIN N AME
FUNCTION, WHILE IN THE
HARDWARE MODE
10
ClkES (SDI)
ClkES
11
FSS (SClk)
FSS
15
BWS/Ch_Addr_1
BWS
18
DJA/(SDO)
DJA
28
Ch_Addr_0
None
29
E3/DS3/(CS)
E3/DS3
S tu ff C o n tro l
HOST MODE:
In Host mode ( connect this pin to VDD), the serial
port interface pins are used to control configuration
and status report. In this mode, serial interface pins :
SDI, SDO,SClk and CS are used.
The Host/HW pin (pin 12) is used to select the operating mode of the XRT71D00. In Hardware mode (connect this pin to ground), the serial processor interface
is disabled and hardwired pins are used to control
configuration and report status..
PIN #
D e jitte rin g &
P o in te r
A d ju s tm e n t
12
XRT71D00
E3/DS3/STS-1 JITTER ATTENUATOR,STS-1 TO DS3 DESYNCHRONIER
REV. 1.01
TABLE 2: ADDRESS AND B IT FORMATS OF THE COMMAND R EGISTERS
ADDR
COMMAND CH_ADDR CH_A DDR
REGISTER
_1
_0
TYPE
D6
D5
D4
D3
D2
D1
D0
0X06
CR6
0
0
R/W
STS-1
0
E3/DS3*
DJA
BWS
ClkES
FSS
0x07
CR7
0
0
RO
***
***
***
***
***
***
FL
0x0E
CR14
0
1
R/W
STS-1
0
E3/DS3*
DJA
BWS
ClkES
FSS
0x0F
CR15
0
1
RO
***
***
***
***
***
***
FL
0x16
CR22
1
0
R/W
STS-1
0
E3/DS3*
DJA
BWS
ClkES
FSS
0x17
CR22
1
0
RO
***
***
***
***
***
***
FL
• The serial interface for both the XRT71D00 and the
XRT7300, XRT7302 and XRT7303, E3/DS3/STS-1
LIU which makes it easy to configure both the
XRT71D00 and the LIU with a single CS, SDI, SDO
and SClk input and output pins.
B IT 8—A6
The value of “A6” is a “don’t care”.
Once these first 8 bits have been written into the Serial Interface, the subsequent action depends upon
whether the current operation is a “Read” or “Write”
operation.
SERIAL INTERFACE OPERATION.
Serial interface data structure and timings are provided in Figure 5 and 6 respectively..
R EAD OPERATION
Once the last address bit (A4) has been clocked into
the SDI input, the “Read” operation will proceed
through an idle period, lasting three SClk periods. On
the falling edge of SClk Cycle #8 (see Figure 5) the
serial data output signal (SDO) becomes active. At
this point the user can begin reading the data contents of the addressed Command Register (at Address [A4,A3, A2, A1, A0]) via the SDO output pin.
The Serial Interface will output this seven bit data
word (D0 through D6) in ascending order (with the
LSB first), on the falling edges of the SClk . The data
(on the SDO output pin) is stable for reading on the
very next rising edge of the SClk .
The clock signal is provided to the SClk and the CS is
asserted for 50 ns prior to the first rising edge of the
SClk.
BIT 1—“R/W” (READ/WRITE) B IT
This bit will be clocked into the SDI input, on the first
rising edge of SClk (after CS has been asserted).
This bit indicates whether the current operation is a
“Read” or “Write” operation. A “1” in this bit specifies
a “Read” operation; whereas, a “0” in this bit specifies
a “Write” operation.
Bits 2 through 5: The five (5) bit Address Values (labeled A0, A1, A2 ,A3,and A4)
W RITE OPERATION
Once the last address bit (A4) has been clocked into
the SDI input, the “Write” operation will proceed
through an idle period, lasting three SClk periods. Prior to the rising edge of SClk Cycle #9 , eight bit data
word is applied to SDI input. Data on SDI is latched
on the rising edge of SClk.
The next four rising edges of the SClk signal will clock
in the 5-bit address value for this particular Read (or
Write) operation. The address selects the Command
Register for reading data from, or writing data to. The
address bits to the SDI input pin is applied in ascending order with the LSB (least significant bit) first.
BIT 7:
A5 must be set to “0”, as shown in Figure 5.
13
E3/DS3/STS-1 JITTER ATTENUATOR,STS-1 TO DS3 DESYNCHRONIER
XRT71D00
REV. 1.01
FIGURE 5. MICROPROCESSOR SERIAL INTERFACE D ATA STRUCTURE
CS
SClk
1
SDI
R/W
2
A0
3
A1
4
A2
5
A3
6
A4
7
0
8
A6
9
10
11
12
13
14
15
16
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
High Z
High Z
SDO
NOTES:
1.
2.
3.
4.
SIMPLIFIED INTERFACE OPTION
The user can simplify the design of the circuitry connecting to the Microprocessor Serial Interface by tying both the SDO and SDI pins together, and reading
data from and/or writing data to this “combined” signal. This simplification is possible because only one
of these signals are active at any given time. The inactive signal will be tri-stated.
A5 is always “0”.
R/W = “1” for “Read” Operations
R/W = “0” for “Write” Operations
Denotes a “don’t care” value (shaded areas)
FIGURE 6. TIMING D IAGRAM FOR THE MICROPROCESSOR SERIAL INTERFACE
t29
t21
CS
t27
t22
t25
SClk
t26
t24
t23
SDI
t28
A0
R/W
A1
CS
SClk
t31
t30
SDO
SDI
Hi-Z
D0
t33
t32
D2
D1
Hi-Z
14
D7
XRT71D00
E3/DS3/STS-1 JITTER ATTENUATOR,STS-1 TO DS3 DESYNCHRONIER
REV. 1.01
FIGURE 7. INPUT/OUTPUT TIMING
ts u
RCLK
RCLK
th
td
RPOS/RNEG
RPOS/RNEG
ClkES = 0
ts u
RCLK
RCLK
th
te
RPOS/RNEG
RPOS/RNEG
ClkES = 1
Table 3 summarizes the results of jitter transfer characteristics testing, performed on the XRT71D00.
Table 4 summarize4s the results of jitter tolerance
testing, performed on the XRT71D00.
TABLE 3: XRT71D00 JITTER TRANSFER FUNCTION
APPLICATION
BWS
DS3
LOW
INPUT JITTER
HIGH
E3
LOW
1UIPP
HIGH
LOW
10UIPP
LOW
1UIPP
Jitter Gain (dB)
FREQ. (HZ)
HIGH
HIGH
10UIPP
Jitter Gain (dB)
5
0.02
-0.33
0.36
0.06
0.44
0.37
0.83
0.04
10
-0.10
-0.10
-0.30
-0.01
-0.15
0.20
-0.22
-0.02
20
-2.04
-0.24
-2.24
-0.13
-3.16
0.35
-3.24
-0.32
30
-3.63
-0.35
-4.33
-0.36
-5.51
0.05
-5.93
-0.73
40
-5.98
-0.53
-6.16
-0.72
-7.68
-0.68
-7.99
-1.24
50
-7.55
-1.00
-7.82
-1.12
-10.36
-1.15
-9.61
-1.85
60
-9.57
-1.46
-9.17
-1.66
-12.50
-2.53
-11.27
-2.45
80
-12.54
-2.25
-11.28
-2.64
-15.20
-3.56
-13.59
-3.76
100
-14.67
-3.07
-13.36
-3.52
-16.22
-4.69
-15.51
-5.02
125
-16.67
-3.88
-14.91
-4.76
-17.38
-5.78
-17.07
-6.50
150
-17.32
-5.74
-16.78
-5.89
-19.45
-7.43
-18.75
-7.74
200
-18.77
-7.75
-18.96
-7.90
-20.36
-10.71
-21.11
-9.94
300
-21.43
-12.04
-21.81
-10.89
-22.96
-13.58
-24.46
-13.23
500
-22.22
-16.74
-26.09
-14.98
-23.78
-17.66
-28.84
-17.16
>1000
-25.42
-21.13
-33.44
-20.66
-23.51
-20.96
-35.77
-23.35
15
E3/DS3/STS-1 JITTER ATTENUATOR,STS-1 TO DS3 DESYNCHRONIER
XRT71D00
REV. 1.01
TABLE 4: XRT71D00 MAXIMUM JITTER TOLERANCE
APPLICATION
BWS
DS3
LOW
FIFO S IZE
HIGH
E3
LOW
16
FREQ. (HZ)
HIGH
LOW
32
HIGH
LOW
16
UI (PEAK TO PEAK)
HIGH
32
UI (PEAK TO PEAK)
10
34.313
>64
>64
>64
26.689
>64
53.313
>64
20
21.439
>64
43.188
>64
18.564
52.188
37.438
>64
30
18.314
46.313
36.813
>64
16.689
36.688
33.938
>64
40
16.939
36.188
34.313
>64
16.064
29.314
32.688
58.438
50
16.314
30.314
33.188
60.313
15.689
25.064
32.063
50.438
60
16.064
26.689
32.563
53.188
15.564
22.564
31.689
45.438
80
15.689
22.314
31.814
44.813
15.314
19.689
31.314
39.688
100
15.439
20.064
31.439
40.434
15.314
18.064
31.189
36.813
125
15.439
18.439
31.314
37.313
15.189
17.064
31.064
34.813
150
15.314
17.564
31.189
35.438
15.189
16.564
31.064
33.688
200
15.314
16.464
31.064
33.563
15.189
15.939
30.939
32.438
300
15.189
15.814
30.939
32.063
15.064
15.564
30.939
31.564
500
15.189
15.439
30.939
31.314
15.064
15.314
30.939
31.189
>1000
15.0189
15.189
30.939
30.939
15.189
15.189
30.939
30.939
16
XRT71D00
E3/DS3/STS-1 JITTER ATTENUATOR, STS-1 TO DS3 DESCYNCHRONIZER
PACKAGE INFORMATION
32 LEAD TQFP PACKAGE DIMENSIONS
ORDERING INFORMATION
PART NUMBER
PACKAGE
OPERATING TEMPERATURE RANGE
XRT71D00IQ
32 Lead TQFP
-400C to +850C
17
XRT71D00
E3/DS3/STS-1 JITTER ATTENUATOR, STS-1 TO DS3
DESCYNCHRONIZER
REVISIONS
NOTICE
EXAR Corporation reserves the right to make changes to the products contained in this publication in order
to improve design, performance or reliability. EXAR Corporation assumes no responsibility for the use of
any circuits described herein, conveys no license under any patent or other right, and makes no representation that the circuits are free of patent infringement. Charts and schedules contained here in are only for
illustration purposes and may vary depending upon a user’s specific application. While the information in
this publication has been carefully checked; no responsibility, however, is assumed for inaccuracies.
EXAR Corporation does not recommend the use of any of its products in life support applications where
the failure or malfunction of the product can reasonably be expected to cause failure of the life support system or to significantly affect its safety or effectiveness. Products are not authorized for use in such applications unless EXAR Corporation receives, in writing, assurances to its satisfaction that: (a) the risk of injury
or damage has been minimized; (b) the user assumes all such risks; (c) potential liability of EXAR Corporation is adequately protected under the circumstances.
Copyright 2000 EXAR Corporation
Datasheet February 2000
Reproduction, in part or whole, without the prior written consent of EXAR Corporation is prohibited.
18