ETC LXT300ZNE

LXT300Z/LXT301Z
Advanced T1/E1 Short-Haul Transceivers
Datasheet
The LXT300Z and LXT301Z are fully integrated transceivers for both North American 1.544
Mbps (T1) and International 2.048 Mbps (E1) applications. They are pin and functionally
compatible with standard LXT300/301 devices, with some circuit enhancements.
The LXT300Z provides receive jitter attenuation starting at 3 Hz, and is microprocessor
controllable through a serial interface. The LXT301Z is pin compatible, but does not provide
jitter attenuation or a serial interface. An advanced transmit driver architecture provides constant
low output impedance for both marks and spaces, for improved Bit Error Rate performance over
various cable network configurations. Both transceivers offer a variety of diagnostic features
including transmit and receive monitoring. Clock inputs may be derived from an on-chip crystal
oscillator or from digital inputs. They use an advanced double-poly, double-metal CMOS
process and require only a single 5-volt power supply.
Applications
■
■
■
■
PCM/Voice Channel Banks
Data Channel Bank/Concentrator
T1/E1 multiplexers
Digital Access and Cross-connect Systems
(DACS)
■
■
■
■
Computer to PBX interfaces (CPI & DMI)
High-speed data transmission lines
Interfacing Customer Premises Equipment
to a CSU
Digital Loop Carrier (DLC) terminals
Product Features
■
■
■
■
■
■
Data recovery and clock recovery functions
Receive jitter attenuation starting at 3 Hz
exceeds AT&T Pub 62411, Pub 43801, Pub
43802, ITU G.703, and ITU G.823
(LXT300Z only)
Line driver with constant low mark and
space impedance (3 Ω typical)
Minimum receive signal of 500 mV
Adaptive and selectable (E1/DSX-1) slicer
levels for improved SNR
Programmable transmit equalizer shapes
pulses to meet DSX-1 pulse template from
0 to 655 feet or drive 120 Ω twisted pair or
75 Ω coax cable for E1
■
■
■
■
■
■
■
Local and remote loopback functions
Digital Transmit Driver Monitor
Digital Receive Monitor with Loss of
Signal (LOS) output and first mark reset
Receiver jitter tolerance 0.4 UI from 40
kHz to 100 kHz
Microprocessor controllable (LXT300Z
only)
Compatible with most popular PCM
framers
Available in 28-pin DIP or PLCC
As of January 15, 2001, this document replaces the Level One document
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers.
Order Number: 249066-001
January 2001
Information in this document is provided in connection with Intel® products. No license, express or implied, by estoppel or otherwise, to any intellectual
property rights is granted by this document. Except as provided in Intel’s Terms and Conditions of Sale for such products, Intel assumes no liability
whatsoever, and Intel disclaims any express or implied warranty, relating to sale and/or use of Intel products including liability or warranties relating to
fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right. Intel products are not
intended for use in medical, life saving, or life sustaining applications.
Intel may make changes to specifications and product descriptions at any time, without notice.
Designers must not rely on the absence or characteristics of any features or instructions marked "reserved" or "undefined." Intel reserves these for
future definition and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future changes to them.
The LXT300Z/LXT301Z may contain design defects or errors known as errata which may cause the product to deviate from published specifications.
Current characterized errata are available on request.
Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order.
Copies of documents which have an ordering number and are referenced in this document, or other Intel literature may be obtained by calling 1-800548-4725 or by visiting Intel’s website at http://www.intel.com.
Copyright © Intel Corporation, 2001
*Third-party brands and names are the property of their respective owners.
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
Contents
1.0
Pin Assignments and Signal Descriptions ...................................................... 6
2.0
Functional Description............................................................................................. 9
2.1
2.2
2.3
2.4
3.0
Power Requirements............................................................................................. 9
2.1.1 Reset Operation (LXT300Z and LXT301Z) ..............................................9
Receiver ..............................................................................................................10
2.2.1 Receive (Loss of Signal) Monitor ...........................................................11
2.2.2 Jitter Attenuation (LXT300Z Only)..........................................................11
Transmitter ..........................................................................................................11
2.3.1 Driver Performance Monitor ...................................................................11
2.3.2 Line Code ...............................................................................................12
Operating Modes.................................................................................................12
2.4.1 Host Mode Operation (LXT300Z Only)...................................................12
2.4.2 Hardware Mode Operation (LXT300Z and LXT301Z) ............................12
2.4.3 Diagnostic Mode Operation....................................................................14
2.4.3.1 Transmit All Ones ......................................................................14
2.4.3.2 Remote Loopback .....................................................................14
2.4.3.3 Local Loopback .........................................................................14
Application Information .........................................................................................16
3.1
3.2
LXT300Z Host Mode 1.544 Mbps T1 Interface ...................................................16
LXT300Z Hardware Mode E1 Interface Application ............................................17
3.2.1 LXT301Z 1.544 Mbps T1 Interface Application ......................................19
3.2.2 LXT301Z 2.048 Mbps E1 Interface Application......................................20
4.0
Test Specifications ..................................................................................................21
5.0
Mechanical Specifications....................................................................................29
Datasheet
3
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
Figures
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
LXT300Z/LXT301Z Block Diagram ....................................................................... 5
LXT300 Pin Assignments and Package Markings ................................................ 6
LXT301Z Block Diagram ..................................................................................... 10
50% AMI Coding ................................................................................................. 13
LXT300Z Serial Interface Data Structure ............................................................ 15
Typical LXT300Z 1.544 Mbps T1 Application (Host Mode)................................. 17
Typical LXT300Z 75 W E1 Application (Hardware Mode)................................... 18
Typical LXT301Z 1.544 Mbps T1 Application ..................................................... 19
Typical LXT301Z 75 W E1 Application................................................................ 20
LXT300Z Typical Receive Jitter Tolerance ......................................................... 23
LXT300Z Typical Receive Jitter Transfer Performance ...................................... 24
LXT300Z Receive Clock Timing Diagram ........................................................... 25
LXT301Z Receive Clock Timing Diagram ........................................................... 26
LXT300Z/301Z Transmit Clock Timing Diagram................................................. 26
LXT300Z Serial Data Input Timing Diagram ....................................................... 27
LXT300Z Serial Data Output Timing Diagram .................................................... 28
Package Specifications ....................................................................................... 29
1
2
3
4
5
6
7
8
9
10
11
12
Pin Descriptions .................................................................................................... 7
LXT300Z Serial Data Output Bits (See Figure 5) ................................................ 13
Valid CLKE Settings............................................................................................ 13
Equalizer Control Inputs...................................................................................... 14
LXT300Z Crystal Specifications (External) ......................................................... 18
Absolute Maximum Ratings ................................................................................ 21
Recommended Operating Conditions ................................................................. 21
Electrical Characteristics..................................................................................... 21
Analog Characteristics ........................................................................................ 22
LXT300Z Receiver Timing Characteristics (See Figure 12)................................ 24
LXT301Z Receive Timing Characteristics (See Figure 13) ................................. 25
LXT300Z/301Z Master Clock and Transmit Timing Characteristics
(See Figure 14) ................................................................................................... 26
LXT300Z Serial I/O Timing Characteristics (See Figure 15 and Figure 16)........ 27
Tables
13
4
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
Figure 1. LXT300Z/LXT301Z Block Diagram
MODE
HOS
T
H/W
EC1
EC2
INT
EC3
SDI
SDO RLOOP
LLOOP
CS
SCLK TAOS
Constant Impedance
Line Driver
Control
TPOS
TNEG
TCLK
Synchronizer
MCLK
Internal Clock
Generator
XTALIN
XTALOUT
RCLK
RPOS
RNEG
LOS
TTIP
TRING
Equalizer
Data Slicers
Timing
Recovery
Peak
Detector
RTIP
Transmit
Driver
Control
MTIP
RRING
Jitter
Attenuator
Elastic
Store
Data
Latch
Receive
Monitor
MRING
DPM
Datasheet
5
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
1.0
Pin Assignments and Signal Descriptions
25
24
23
22
21
20
19
TAOS
LLOOP
RLOOP
EC3
EC2
EC1
RGND
RV+
RRING
RTIP
MRING
MTIP
TRING
TV+
TNEG
TPOS
TCLK
MCLK
TAOS
LLOOP
RLOOP
28
27
26
25
24
23
22
21
20
19
18
17
16
15
SDO / EC3
SDI / EC2
INT / EC1
RGND
RV+
RRING
RTIP
GND
RNEG
RPOS
RCLK
RT
N/C
DPM
5
6
7
LXT301ZPE XX
8 XXXXXX
9 XXXXXXXX
10
11
25
24
23
22
21
20
19
EC3
EC2
EC1
RGND
RV+
RRING
RTIP
LOS
TTIP
TGND
TV+
TRING
MTIP
MRING
4
3
2
1
28
27
26
12
13
14
15
16
17
18
5
6
7 LXT300ZPE XX
8 XXXXXX
9 XXXXXXXX
10
11
LOS
TTIP
TGND
TV+
TRING
MTIP
MRING
MODE
RNEG
RPOS
RCLK
XTALIN
XTALOUT
DPM
1
2
3
4
5
6
7
8
9
10
11
12
13
14
LXT301ZNE
MCLK
TCLK
TPOS
TNEG
GND
RNEG
RPOS
RCLK
RT
N/C
DPM
LOS
TTIP
TGND
CLKE / TAOS
SCLK / LLOOP
CS / RLOOP
SDO / EC3
SDI / EC2
INT / EC1
RGND
RV+
RRING
RTIP
MRING
MTIP
TRING
TV+
4
3
2
1
28
27
26
28
27
26
25
24
23
22
21
20
19
18
17
16
15
12
13
14
15
16
17
18
1
2
3
4
5
6
7
8
9
10
11
12
13
14
TNEG
TPOS
TCLK
MCLK
CLKE / TAOS
SCLK / LLOOP
CS / RLOOP
MCLK
TCLK
TPOS
TNEG
MODE
RNEG
RPOS
RCLK
XTALIN
XTALOUT
DPM
LOS
TTIP
TGND
LXT300ZNE
Figure 2. LXT300 Pin Assignments and Package Markings
Package Topside Markings
Marking
Part #
Unique identifier for this product family.
Rev #
Identifies the particular silicon “stepping” — refer to the specification update for additional stepping information.
Lot #
Identifies the batch.
FPO #
6
Definition
Identifies the Finish Process Order.
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
Table 1.
Pin Descriptions
Pin #
Sym
I/O1
1
MCLK
DI
Description
Master Clock. A 1.544 or 2.048 MHz clock input used to generate internal clocks. Upon
Loss of Signal (LOS), RCLK is derived from MCLK.
LXT300Z Only: If MCLK is not applied, this pin must be grounded.
2
TCLK
DI
Transmit Clock. Transmit clock input. TPOS and TNEG are sampled on the falling edge of
TCLK. If TCLK is grounded, the output drivers enter a high-Z state, except during Remote
Loopback.
3
TPOS
DI
Transmit Positive Data. Input for positive pulse to be transmitted on the twisted-pair line or
coax.
4
TNEG
DI
Transmit Negative Data. Input for negative pulse to be transmitted on the twisted-pair line.
MODE
DI
Mode Select (LXT300Z). Setting MODE High puts the LXT300Z in the Host mode. In the Host
mode, the serial interface is used to control the LXT300Z and determine its status. Setting
MODE Low puts the LXT300Z in the Hardware (H/W) mode. In the Hardware mode, the serial
interface is disabled and hard-wired pins are used to control configuration and report status.
GND
S
Ground (LXT301Z). Tie to Ground.
6
RNEG
DO
Receive Negative Data; Receive Positive Data. Received data outputs. A signal on RNEG
corresponds to receipt of a negative pulse on RTIP and RRING. A signal on RPOS
corresponds to receipt of a positive pulse on RTIP and RRING. RNEG and RPOS outputs are
Non-Return-to-Zero (NRZ). Both outputs are stable and valid on the rising edge of RCLK.
7
RPOS
DO
LXT300Z only: In the Host mode, CLKE determines the clock edge at which these outputs are
stable and valid. In the Hardware mode both outputs are stable and valid on the rising edge of
RCLK.
8
RCLK
DO
Recovered Clock. This is the clock recovered from the signal received at RTIP and RRING.
5
RT
AI
Receive Termination (LXT301Z). Connect to RV+ through a 1 kΩ resistor.
XTALIN
AI
10
XTALOUT
AO
Crystal Input; Crystal Output (LXT300Z). An external crystal operating at four times the bit
rate (6.176 MHz for DSX-1, 8.192 MHz for E1 applications with an
18.7 pF load) is required to enable the jitter attenuation function of the LXT300Z. These pins
may also be used to disable the jitter attenuator by connecting the XTALIN pin to the positive
supply through a resistor, and floating the XTALOUT pin.
10
N/C
–
11
DPM
DO
Driver Performance Monitor. DPM goes High when the transmit monitor loop (MTIP and
MRING) does not detect a signal for 63 ±2 clock periods. DPM remains High until a signal is
detected.
12
LOS
DO
Loss of Signal. LOS goes High when 175 consecutive spaces have been detected from
receive. LOS returns Low when a mark is detected from the receiver.
13
TTIP
AO
16
TRING
AO
14
TGND
S
Transmit Ground. Ground return for the transmit driver power supply TV+.
15
TV+
S
Transmit Driver Power Supply. +5 VDC power supply input for the transmit drivers. TV+
must not vary from RV+ by more than ±0.3 V.
17
MTIP
AI
18
MRING
AI
9
No Connection (LXT301Z).
Transmit Tip; Transmit Ring. Differential Driver Outputs. These outputs are designed to
drive a 25 Ω load. The transmitter will drive 100 Ω shielded twisted-pair cable through a 1:2
step-up transformer without additional components. To drive
75 Ω coaxial cable, two 2.2 Ω resistors are required in series with the transformer.
Monitor Tip; Monitor Ring. These pins are used to monitor the tip and ring transmit outputs.
The transceiver can be connected to monitor its own output or the output of another LXT300Z
or LXT301Z on the board.
1. DI = Digital Input; DO = Digital Output; AI = Analog Input; AO = Analog Output; S = Supply.
Datasheet
7
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
Table 1.
Pin Descriptions (Continued)
Pin #
Sym
I/O1
Description
19
RTIP
AI
20
RRING
AI
Receive Tip; Receive Ring. The AMI signal received from the line is applied at these pins. A
center-tapped, center-grounded, 2:1 step-up transformer is required on these pins. Data and
clock from the signal applied at these pins are recovered and output on the RPOS/RNEG and
RCLK pins.
21
RV+
S
Receive Power Supply. +5 VDC power supply for all circuits except the transmit drivers.
(Transmit drivers are supplied by TV+.)
22
RGND
S
Receive Ground. Ground return for power supply RV+.
INT
DO
Interrupt (LXT300Z - Host Mode). This output goes Low to flag the host processor when
LOS or DPM go active. INT is an open-drain output and should be tied to power supply RV+
through a resistor. INT is reset by clearing the respective register bit (LOS and/or DPM).
EC1
DI
Equalizer Control 1 (LXT301Z and LXT300Z - H/W Mode). The signal applied at this pin is
used in conjunction with EC2 and EC3 inputs to determine shape and amplitude of AMI output
transmit pulses.
SDI
DI
Serial Data In (LXT300Z - Host Mode). The serial data input stream is applied to this pin. SDI
is sampled on the rising edge of SCLK.
EC2
DI
Equalizer Control 2 (LXT301Z and LXT300Z - H/W Mode). The signal applied at this pin is
used in conjunction with EC1 and EC3 inputs to determine shape and amplitude of AMI output
transmit pulses.
SDO
DO
Serial Data Out (LXT300Z - Host Mode). The serial data from the on-chip register is output
on this pin. If CLKE is High, SDO is valid on the rising edge of SCLK. If CLKE is Low SDO is
valid on the falling edge of SCLK. This pin goes to a high-impedance state when the serial
port is being written to and when CS is High.
EC3
DI
Equalizer Control 3 (LXT301Z and LXT300Z - H/W Mode). The signal applied at this pin is
used in conjunction with EC1 and EC2 inputs to determine shape and amplitude of AMI output
transmit pulses.
CS
DI
Chip Select (LXT300Z - Host Mode). This input is used to access the serial interface. For
each read or write operation, CS must transition from High to Low, and remain Low.
RLOOP
DI
Remote Loopback (LXT301Z and LXT300Z - H/W Mode). Setting RLOOP High enables the
Remote Loopback mode. Setting both RLOOP and LLOOP High causes a Reset.
SCLK
DI
Serial Clock (LXT300Z - Host Mode). This clock is used to write data to or read data from the
serial interface registers.
LLOOP
DI
Local Loopback (LXT301Z and LXT300Z - H/W Mode). This input controls loopback
functions. Setting LLOOP High enables the Local Loopback mode.
CLKE
DI
Clock Edge (LXT300Z - Host Mode). Setting CLKE High causes RPOS and RNEG to be
valid on the falling edge of RCLK, and SDO to be valid on the rising edge of SCLK. When
CLKE is Low, RPOS and RNEG are valid on the rising edge of RCLK, and SDO is valid on the
falling edge of SCLK.
TAOS
DI
Transmit All Ones (LXT301Z and LXT300Z - H/W Mode). When High, a continuous stream
of marks is transmitted at the TCLK frequency. Activating TAOS causes TPOS and TNEG
inputs to be ignored. TAOS is inhibited during Remote Loopback.
23
24
25
26
27
28
1. DI = Digital Input; DO = Digital Output; AI = Analog Input; AO = Analog Output; S = Supply.
8
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
2.0
Functional Description
The LXT300Z and LXT301Z are fully integrated PCM transceivers for both 1.544 Mbps (DSX-1)
and 2.048 Mbps (E1) applications. Both transceivers allow full-duplex transmission of digital data
over existing twisted-pair or coax installations. The first page of this data sheet shows a simplified
block diagram of the LXT300Z and Figure 3 shows the LXT301Z. The LXT301Z is similar to the
LXT300Z, but does not incorporate the Jitter Attenuator and associated Elastic Store, nor the serial
interface port.
The LXT300Z and LXT301Z transceivers each interface with two twisted-pair or coax lines (one
pair or coax for transmit, one pair or coax for receive) through standard pulse transformers and
appropriate resistors.
2.1
Power Requirements
The LXT300Z and LXT301Z are low-power CMOS devices. Each operates from a single +5 V
power supply which can be connected externally to both the transmitter and receiver. However, the
two inputs must be within ±0.3V of each other, and decoupled to their respective grounds
separately. Refer to “Application Information” on page 16 for typical decoupling circuitry.
Isolation between the transmit and receive circuits is provided internally.
2.1.1
Reset Operation (LXT300Z and LXT301Z)
Upon power up, the transceiver is held static until the power supply reaches approximately 3 V.
Upon crossing this threshold, the device begins a 32 ms reset cycle to calibrate the transmit and
receive delay lines and lock the Phase Lock Loop (PLL) to the receive line. A reference clock is
required to calibrate the delay lines. The transmitter reference is provided by TCLK. MCLK
provides the receiver reference for the LXT301Z. The crystal oscillator provides the receiver
reference in the LXT300Z. If the LXT300Z crystal oscillator is grounded, MCLK is used as the
receiver reference clock.
The transceiver can also be reset from the Host mode or Hardware mode. In Host mode, reset is
commanded by simultaneously writing RLOOP and LLOOP to the register. In Hardware mode,
reset is commanded by holding RLOOP and LLOOP High simultaneously for 200 ns. Reset is
initiated on the falling edge of the reset request. In either mode, the reset clears and sets all registers
to 0 and then calibration begins.
Datasheet
9
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
Figure 3. LXT301Z Block Diagram
EC1, EC2, EC3
TPOS
TNEG
TCLK
Synchronizer
MCLK
Internal Clock
Generator
RCLK
RPOS
RNEG
LOS
Constant Impedance
Line Driver
Control
TTIP
Equalizer
TRING
Data Slicers
Timing
Recovery
Data
Latch
Receive
Monitor
Peak
Detector
Transmit
Driver
Monitor
RTIP
RRING
MTIP
MRING
DPM
2.2
Receiver
The LXT300Z and LXT301Z receivers are identical except for the Jitter Attenuator and Elastic
Store. The following discussion applies to both transceivers except where noted.
The signal is received from one twisted-pair line on each side of a center-grounded transformer.
Positive pulses are received at RTIP and negative pulses are received at RRING. Recovered data is
output at RPOS and RNEG, and the recovered clock is output at RCLK. Refer to the “Test
Specifications” section of this data sheet for receiver timing.
The signal received at RPOS and RNEG is processed through the peak detector and data slicers.
The peak detector samples the inputs and determines the maximum value of the received signal. A
percentage of the peak value is provided to the data slicers as a threshold level to ensure optimum
signal-to-noise ratio. For DSX-1 applications (determined by Equalizer Control inputs EC1~EC3 ≠
000) the threshold is set to 70% of the peak value. This threshold is maintained above 65% for up
to 15 successive zeros over the range of specified operating conditions. For E1 applications (EC
inputs = 000) the threshold is set to 50%.
The receiver is capable of accurately recovering signals with up to -13.6 dB of attenuation (from
2.4 V), corresponding to a received signal level of approximately 500 mV. Maximum line length is
1500 feet of ABAM cable (approximately 6 dB). Regardless of received signal level, the peak
detectors are held above a minimum level of 300 mV to provide immunity from impulsive noise.
Note that during a Loss of Signal (LOS) condition, RPOS and RNEG are squelched if the received
input signal drops below 300 mV.
After processing through the data slicers, the received signal is routed to the data and clock
recovery sections, and to the receive monitor. In the LXT300Z only, recovered clock signals are
supplied to the jitter attenuator and the data latch. The recovered data is passed to the elastic store
where it is buffered and synchronized with the dejittered recovered clock (RCLK). The data and
clock recovery circuits have an input jitter tolerance significantly better than required by Pub
62411.
10
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
2.2.1
Receive (Loss of Signal) Monitor
The receive monitor generates a Loss of Signal (LOS) output upon receipt of 175 consecutive zeros
(spaces). The receiver monitor loads a digital counter at the RCLK frequency. The count is
incremented each time a zero is received, and reset to zero each time a one (mark) is received.
Upon receipt of 175 consecutive zeros the LOS pin goes High, and the RCLK output is replaced
with MCLK. LOS is reset when the first mark is received.
(In the LXT300Z only, if MCLK is not supplied, the RCLK output will be replaced with the centered
crystal clock.)
2.2.2
Jitter Attenuation (LXT300Z Only)
In the LXT300Z, recovered clock signals are supplied to the jitter attenuator and the data latch. The
recovered data is passed to the elastic store where it is buffered and synchronized with the
dejittered recovered clock (RCLK). Jitter attenuation of the LXT300Z clock and data outputs (see
Figure 5) is provided by a Jitter Attenuation Loop (JAL) and an Elastic Store (ES). An external
crystal oscillating at 4 times the bit rate provides clock stabilization. Refer to page 18 for crystal
specifications. The ES is a 32 x 2-bit register. Recovered data is clocked into the ES with the
recovered clock signal, and clocked out of the ES with the dejittered clock from the JAL. When the
bit count in the ES is within two bits of overflowing or underflowing, the ES adjusts the output
clock by 1/8 of a bit period. The ES produces an average delay of 16 bits in the receive path.
2.3
Transmitter
The transmitter circuits in the LXT300Z and LXT301Z are identical. The following discussion
applies to both devices. Data received for transmission onto the line is clocked serially into the
device at TPOS and TNEG. Input synchronization is supplied by the transmit clock (TCLK). The
transmitted pulse shape is determined by Equalizer Control signals EC1 through EC3 as shown in
Table 4. Refer to the “Test Specifications” section of this data sheet for master and transmit clock
timing characteristics. Shaped pulses are applied to the AMI line driver for transmission onto the
line at TTIP and TRING. Equalizer Control signals are hard-wired in the LXT301Z.
LXT300Z Only: Equalizer Control signals may be hardwired in the Hardware mode, or input as
part of the serial data stream (SDI) in the Host mode.
Pulses can be shaped for either 1.544 or 2.048 Mbps applications. DSX-1 applications with 1.544
Mbps pulses can be programmed to match line lengths from 0 to 655 feet of ABAM cable. The
LXT300Z and LXT301Z also match FCC specifications for CSU applications. Pulses at 2.048
Mbps can drive coaxial or shielded twisted-pair lines using appropriate resistors in line with the
output transformer.
2.3.1
Driver Performance Monitor
The transceiver incorporates an advanced Driver Performance Monitor (DPM) in parallel with the
TTIP and TRING at the output transformer. The DPM circuitry uses four comparators and a 150 ns
pulse discriminator to filter glitches. The DPM output level goes High upon detection of 63
consecutive zeros, and is cleared when a one is detected on the transmit line, or when a reset
command is received. The DPM output also goes High to indicate a ground on TTIP or TRING. A
ground fault induced DPM flag is automatically cleared when the ground condition is corrected
(chip reset is not required).
Datasheet
11
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
2.3.2
Line Code
The LXT300Z and LXT301Z transmit data as a 50% AMI line code as shown in Figure 4. Power
consumption is reduced by activating the AMI line driver only to transmit a mark. The output
driver is disabled during transmission of a space.
2.4
Operating Modes
The LXT300Z and LXT301Z transceivers can be controlled through hard-wired pins (Hardware
mode). Both transceivers can also be commanded to operate in one of several diagnostic modes.
LXT300Z Only: The LXT300Z can be controlled by a microprocessor through a serial interface
(Host mode). The mode of operation is set by the MODE pin logic level.
2.4.1
Host Mode Operation (LXT300Z Only)
To allow a host microprocessor to access and control the LXT300Z through the serial interface,
MODE is set to 1. The serial interface (SDI/SDO) uses a 16-bit word consisting of an 8-bit
Command/Address byte and an 8-bit Data byte. Figure 5 shows the serial interface data structure
and relative timing.
The Host mode provides a latched Interrupt output (INT) which is triggered by a change in the
Loss of Signal (LOS) and/or Driver Performance Monitor (DPM) bits. The Interrupt is cleared
when the interrupt condition no longer exists, and the host processor enables the respective bit in
the serial input data byte. Host mode also allows control of the serial data and receive data output
timing. The Clock Edge (CLKE) signal determines when these outputs are valid, relative to the
Serial Clock (SCLK) or RCLK as listed in Table 3.
The LXT300Z serial port is addressed by setting bit A4 in the Address/Command byte,
corresponding to address 16. The LXT300Z contains only a single output data register so no
complex chip addressing scheme is required. The register is accessed by causing the Chip Select
(CS) input to transition from High to Low. Bit 1 of the serial Address/Command byte provides
Read/Write control when the chip is accessed. A logic 1 indicates a read operation, and a logic 0
indicates a write operation. Table 4 lists serial data output bit combinations for each status. Serial
data I/O timing characteristics are shown in the Test Specifications section.
2.4.2
Hardware Mode Operation (LXT300Z and LXT301Z)
In Hardware mode the transceiver is accessed and controlled through individual pins. With the
exception of the INT and CLKE functions, Hardware mode provides all the functions provided in
the Host mode. In the Hardware mode RPOS and RNEG outputs are valid on the rising edge of
RCLK. The LXT301Z operates in Hardware mode at all times.
LXT300Z Only: To operate in Hardware mode, MODE must be set Low. Equalizer Control signals
(EC1 through EC3) are input on the Interrupt, Serial Data In and Serial Data Out pins respectively.
Diagnostic control for Remote Loopback (RLOOP), Local Loopback (LLOOP), and Transmit All
Ones (TAOS) modes is provided through the individual pins used to control serial interface timing
in the Host mode.
12
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
Figure 4. 50% AMI Coding
Bit Cell
TTIP
1
0
1
TRING
Table 2.
LXT300Z Serial Data Output Bits (See Figure 5)
Bit
D5
Bit
D6
Bit
D7
0
0
0
Reset has occurred, or no program input.
0
0
1
TAOS is active.
0
1
0
Local Loopback is active.
0
1
1
TAOS and Local Loopback are active.
1
0
0
Remote Loopback is active.
1
0
1
DPM has changed state since last Clear DPM occurred.
1
1
0
LOS has changed state since last Clear LOS occurred.
1
1
1
LOS and DPM have both changed state since last Clear DPM and Clear LOS
occurred.
Table 3.
Status
Valid CLKE Settings
CLKE
Output
Clock
Valid Edge
RPOS
RCLK
Rising
Low
RNEG
RCLK
Rising
SDO
SCLK
Falling
High
Datasheet
RPOS
RCLK
Falling
RNEG
RCLK
Falling
SDO
SCLK
Rising
13
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
Table 4.
Equalizer Control Inputs
Line Length1
Cable Loss2
1
0 ~ 133 ft ABAM
0.6 dB
0
133 ~ 266 ft ABAM
1.2 dB
0
1
266 ~ 399 ft ABAM
1.8 dB
1
0
399 ~ 533 ft ABAM
2.4 dB
533 ~ 655 ft ABAM
3.0 dB
EC3
EC2
EC1
0
1
1
0
1
1
Application
Bit Rate
DSX-1
1.544 Mbps
1
1
1
0
0
0
ITU Recommendation G.703
E1
2.048 Mbps
0
1
0
FCC Part 68, Option A
CSU
1.544 Mbps
1. Line length from transceiver to DSX-1 cross-connect point.
2. Maximum cable loss at 772 kHz.
2.4.3
Diagnostic Mode Operation
2.4.3.1
Transmit All Ones
In Transmit All Ones (TAOS) mode, the TPOS and TNEG inputs to the transceiver are ignored.
The transceiver transmits a continuous stream of ones. TAOS can be commanded simultaneously
with Local Loopback, but is inhibited during Remote Loopback.
2.4.3.2
Remote Loopback
In Remote Loopback (RLOOP) mode, the transmit data and clock inputs (TPOS, TNEG and
TCLK) are ignored. The RPOS and RNEG outputs are looped back through the transmit circuits
and output on TTIP and TRING at the RCLK frequency. Receiver circuits are unaffected by the
RLOOP command and continue to output the RPOS, RNEG and RCLK signals received from the
twisted-pair line.
2.4.3.3
Local Loopback
In Local Loopback (LLOOP) mode, the receiver circuits are inhibited. The transmit data and clock
inputs (TPOS, TNEG and TCLK) are looped back onto the receive data and clock outputs (RPOS,
RNEG and RCLK) through the receive jitter attenuator. The transmitter circuits are unaffected by
the LLOOP command. The TPOS and TNEG inputs (or a stream of ones if the TAOS command is
active) will be transmitted normally.
LXT300Z Only: When used in this mode with a crystal, the transceiver can be used as a stand-alone
jitter attenuator.
14
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
Figure 5. LXT300Z Serial Interface Data Structure
CS
SCLK
ADDRESS / COMMAND BYTE
SDI/ SDO
R/W
A0
A1
A2
A3
A4
DATA INPUT / OUTPUT BYTE
A5
A6
D0
D1
D2
D3
D4
D5
D6
D7
NOTE:
ADDRESS /
COMMAND
BYTE
R/W
0
0
0
0
A0
1
Datasheet
LOS
D0 (LSB)
DFM
X
R/W- = 1: Read
A6
R/W- = 0: Write
X=DON’T CARE
CLEAR INTERRUPTS
INPUT
DATA
BYTE
0
A4
EC1
EC2
EC3
Output data byte is
the same as the input
data byte except for
bits D<5:7> shown in
Table 2.
SET LOOPBACKS OR RESET
REMOTE
LOCAL
TAOS
D7(MSB)
15
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
3.0
Application Information
3.1
LXT300Z Host Mode 1.544 Mbps T1 Interface
Figure 6 shows a typical 1.544 Mbps T1 application. The LXT300Z is configured in the Host mode
with a typical T1/ESF framer providing the digital interface with the host controller. Both devices
are controlled through the serial interface. The LXP600A Clock Adapter (CLAD) provides the
2.048 MHz system backplane clock, locked to the recovered 1.544 MHz clock signal. The power
supply inputs are tied to a common bus with appropriate decoupling capacitors installed (68 µF on
the transmit side, 1.0 µF and 0.1 µF on the receive side).
16
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
Figure 6. Typical LXT300Z 1.544 Mbps T1 Application (Host Mode)
TO HOST CONTROLLER
T1 ESF
FRAMER
TMSYNC
1.544 MHz
CLOCK
LXT300Z
TRANSCEIVER
TFSYNC
MCLK
CLKE
CS
TCLK
TCLK
SCLK
SDO
TPOS
TPOS
CS
SDI
TNEG
TNEG
SDO
INT
SPS
MODE
SDI
RNEG
RNEG
INT
RPOS
RPOS
RGND
RCLK
RV+
+V
V+
22 K Ω
SCLK
0V
0.1 µF
RCLK
1.544 MHz
NOTE 1
1 µF
RRING
XTALIN
6.176 MHz
LXP600A/602
CLKI
CLAD
NOTE 1
1 : 1 :1
T1 LINE
RECEIVE
200 Ω
CLKO
2.048 MHz
NOTE 2
200 Ω
RTIP
XTALOUT
FSI
THE LXT300Z IS COMPATIBLE WITH A WIDE
VARIETY OF DIGITAL FRAMING AND
SIGNALING DEVICES.
DPM
MRING
LOS
MTIP
TTIP
TRING
NONPOLARIZED
0.47 µF
1.544 MHz
T1 LINE
TRANSMIT
1:2
NOTE 2
3.2
WHEN LXT300Z IS CONNECTED TO THE
CROSS-CONNECT FRAME THROUGH A LOW
LEVEL MONITOR JACK, RECEIVE
TRANSFORMER SHOULD BE 1 : 2 : 2 TO
BOOST THE INPUT SIGNAL.
TV+
TGND
68 µ F
+V
LXT300Z Hardware Mode E1 Interface Application
Figure 7 shows a typical 2.048 Mbps E1 application. The LXT300Z is configured in Hardware
mode with a typical E1/CRC4 framer. Resistors are installed in line with the transmit transformer
for loading a 75 Ω coaxial cable. The in-line resistors are not required for transmission on 120 Ω
shielded twisted-pair lines. As in the T1 application shown in Figure 6, this configuration is
illustrated with a crystal in place to enable the LXT300Z Jitter Attenuation Loop, and a single
Datasheet
17
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
power supply bus. The hard-wired control lines for TAOS, LLOOP and RLOOP are individually
controllable, and the LLOOP and RLOOP lines are also tied to a single control for the Reset
function
Figure 7. Typical LXT300Z 75 Ω E1 Application (Hardware Mode)
E1/CRC4
FRAMER
LXT300Z
2.048 MHz
Clock
100 kΩ
TRANSCEIVER
V+
NOTE 2
MCLK
TAOS
TCLK
TCLK
LLOOP
TPOS
TPOS
RLOOP
TNEG
TNEG
EC3
MODE
EC2
RNEG
RNEG
EC1
RPOS
RPOS
RGND
RCLK
RCLK
RV+
XTALIN
220 kΩ
10 kΩ
10 kΩ
0V
0.1 µF
+ 1 µF
RRING
8.192 MHz
XTALOUT
150 Ω
RTIP
1:1:1
2.048 Mbps
RECEIVE
150 Ω
NOTE 1
NOTE 2
Table 5.
2.2 Ω RESISTORS REQUIRED
ONLY FOR 75 Ω COAXIAL CABLE.
NOT REQUIRED FOR
TRANSMISSION ONTO 120 Ω
CABLE.
THE LXT300Z IS COMPATIBLE
WITH A WIDE VARIETY OF
FRAMING AND SIGNALING
DEVICES, INCLUDING THE
DS2181A, MT8979, AND R8070.
DPM
MRING
LOS
MTIP
TTIP
TRING
NON-POLARIZED
1:2
0.47 µ F
TGND
2.2 Ω
TV+
2.048 Mbps
TRANSMIT
2.2 Ω
NOTE 1
+ 68 µ F
V+
LXT300Z Crystal Specifications (External)
Parameter
T1
E1
Frequency
6.176 MHz
8.192 MHz
Frequency stability
± 20 ppm @ 25 °C
± 25 ppm from -40 °C to 85 °C
(Ref 25 °C reading)
± 20 ppm @ 25 °C
± 25 ppm from -40 °C to +85 °C
(Ref 25 °C reading)
Pullability
CL = 11 pF to 18.7 pF, +∆F = 175 to 195 ppm
CL = 18.7 pF to 34 pF, -∆F = 175 to 195 ppm
CL = 11 pF to 18.7 pF, +∆F = 95 to 115 ppm
CL = 18.7 pF to 34 pF, -∆F = 95 to 115 ppm
Effective series
resistance
40 Ω Maximum
30 Ω Maximum
Crystal cut
AT
AT
Resonance
Parallel
Parallel
Maximum drive level
2.0 mW
2.0 mW
Mode of operation
Fundamental
Fundamental
Crystal holder
18
HC49 (R3W),
CO = 7 pF maximum
CM = 17 fF typical
HC49 (R3W),
CO = 7 pF maximum
CM = 17 fF typical
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
3.2.1
LXT301Z 1.544 Mbps T1 Interface Application
Figure 8 shows a typical 1.544 Mbps T1 application of the LXT301Z. The LXT301Z is shown with
a typical T1/ESF framer. The LXP600A Clock Adapter (CLAD) provides the 2.048 MHz system
backplane clock, locked to the recovered 1.544 MHz clock signal. The power supply inputs are tied
to a common bus with appropriate decoupling capacitors installed (68 µF on the transmit side, 1.0
µF and 0.1 µF on the receive side).
Figure 8. Typical LXT301Z 1.544 Mbps T1 Application
T1/ESF
FRAMER
LXT301Z
1.544 MHz
Clock
100 kΩ
TRANSCEIVER
V+
NOTE 1
MCLK
TAOS
TCLK
TCLK
LLOOP
TPOS
TPOS
RLOOP
TNEG
TNEG
EC3
GND
EC2
RNEG
RNEG
EC1
RPOS
RPOS
RGND
RCLK
RV+
1.544 MHz
RCLK
220 kΩ
10 kΩ
10 kΩ
0V
0.1 µF
1 µF
V+
1 kΩ
RT
RRING
E1.5i
200 Ω
N/C
LX600A / 602
CLKI
CLAD
2.048 MHz
RTIP
DPM
MRING
LOS
MTIP
1:1:1
T1 LINE
RECEIVE
200 Ω
CLKO
FSI
NON-POLARIZED
1:2
0.47 µF
TTIP
TRING
1.544 Mbps
TRANSMIT
NOTE 1
Datasheet
THE LXT300Z IS COMPATIBLE
WITH A WIDE VARIETY OF
FRAMING AND SIGNALING
DEVICES.
TGND
+ 68 µF
TV+
V+
19
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
3.2.2
LXT301Z 2.048 Mbps E1 Interface Application
Figure 9 shows a typical 2.048 Mbps E1 application of the LXT301Z. The LXT301Z is shown with
a typical E1/CRC4 framer. Resistors are installed in line with the transmit transformer for loading a
75 Ω coaxial cable. The in-line resistors are not required for transmission on 120 Ω shielded
twisted-pair lines. As in the T1 application shown in Figure 8, this configuration is illustrated with
a single power supply bus. The hard-wired control lines for TAOS, LLOOP and RLOOP are
individually controllable, and the LLOOP and RLOOP lines are also tied to a single control for the
Reset function.
Figure 9. Typical LXT301Z 75 Ω E1 Application
E1/CRC4
FRAMER
LXT301Z
2.048 MHz
Clock
100 kΩ
TRANSCEIVER
V+
NOTE 1
MCLK
TAOS
TCLK
TCLK
LLOOP
TPOS
TPOS
RLOOP
TNEG
TNEG
EC3
GND
EC2
RNEG
RNEG
EC1
RPOS
RPOS
RGND
RCLK
RCLK
RV+
v+
RT
220 kΩ
10 kΩ
10 kΩ
0V
0.1 µF
+ 1 µF
RRING
N/C
RTIP
150 Ω
150 Ω
NOTE 1
THE LXT301Z IS COMPATIBLE
WITH A WIDE VARIETY OF
FRAMING AND SIGNALING
DEVICES.
DPM
MRING
LOS
MTIP
1:1:1
2.048 Mbps
RECEIVE
NON-POLARIZED
1:2
0.47 µF
TTIP
TRING
TGND
+ 68 µF
TV+
2.2 Ω
2.048 Mbps
TRANSMIT
2.2 Ω
V+
300zf08.vsd
20
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
4.0
Test Specifications
Note:
Table 6.
Table 6 through Table 13 and Figure 10 through Figure 16 represent the performance specifications
of the LXT300Z/301Z and are guaranteed by test except, where noted, by design. The minimum
and maximum values listed in Table 8 through Table 13 are guaranteed over the recommended
operating conditions specified in Table 7.
Absolute Maximum Ratings
Parameter
DC supply (referenced to GND)
Min
Max
Units
RV+, TV+
-0.3
6.0
V
1
VIN
RGND - 0.3
RV+ + 0.3
V
2
Iin
-10
10
mA
TSTG
-65
150
°C
Input voltage, any pin
Input current, any pin
Sym
Storage temperature
Caution: Exceeding these values may cause permanent damage.
Caution: Functional operation under these conditions is not implied.
Caution: Exposure to maximum rating conditions for extended periods may affect device reliability.
1. Excluding RTIP and RRING which must stay between -6V and (RV+ + 0.3) V.
2. Transient currents of up to 100 mA will not cause SCR latch up. TTIP, TRING, TV+ and TGND can withstand a continuous
current of 100 mA.
Table 7.
Recommended Operating Conditions
Parameter
DC supply1
Sym
Min
Typ
Max
RV+, TV+
4.75
5.0
5.25
V
TA
-40
25
85
°C
Ambient operating temperature
Units
1. TV+ must not exceed RV+ by more than 0.3 V.
Table 8.
Electrical Characteristics
Parameter
1,2
1,2
High level input voltage
Sym
Min
Typ
Max
Units
(pins 1-5, 10, 23-28)
VIH
2.0
–
–
V
(pins 1-5, 10, 23-28)
–
0.8
V
Test Conditions
Vil
–
1,2
(pins 6-8, 11, 12, 23, 25)
VOH
2.4
–
–
V
IOUT = -400 µA
Low level output voltage1,2 (pins 6-8, 11, 12, 23, 25)
VOL
–
–
0.4
V
IOUT = 1.6 mA
Input leakage current (pins 1-5, and 23-28)
ILL
-10
–
+10
µA
Input leakage current (pins 9, 17, and 18)
ILL
-50
–
+50
µA
Three-state leakage current (pin 25)
I3L
-10
–
+10
µA
Total power dissipation3
PD
–
–
700
mW
Low level input voltage
High level output voltage
1
100% ones density &
maximum line length
@ 5.25 V
1. Functionality of pins 23 through 28 depends on mode. See Host and Hardware mode functional descriptions.
2. Output drivers will output CMOS logic levels into CMOS loads.
3. Power dissipation while driving a 25 Ω load over operating temperature range. Includes device and load. Digital input levels
are within 10% of the supply rails and digital outputs are driving a 50 pF capacitive load.
Datasheet
21
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
Table 9.
Analog Characteristics
Parameter
AMI output pulse amplitudes
Min
Typ1
Max
Units
Test Conditions
DSX-1
2.4
3.0
3.6
V
measured at the DSX
E1 (120 Ω)
2.7
3.0
3.3
V
measured at line side
E1 (75 Ω)
2.14
2.37
2.6
V
@ 772 kHz
1
2.5
%
Transmit amplitude variation with supply
Recommended output load at TTIP and TRING
–
25
–
Ω
RTIP to RRING
Driver output impedance2
–
3
10
Ω
@ 10 kHz
2
–
–
0.02
UI
8 kHz - 40 kHz
–
–
0.025
UI
10 Hz - 40 kHz
–
–
0.025
UI
Broad Band
–
–
0.05
UI
12.6
–
17.9
dBm
-29.0
–
–
dB
10 Hz - 8 kHz
Jitter added by the transmitter3
Output power levels2
DS1 2 kHz BW
@ 772 kHz
@ 1544 kHz
5
Positive to negative pulse imbalance
Sensitivity below DSX6 (0 dB = 2.4 V)
Receiver input impedance
Loss of Signal threshold
–
–
0.5
dB
13.6
–
–
dB
500
–
–
mV
–
40
–
kΩ
–
0.3
–
V
DSX-1
63
70
77
% peak
E1
43
50
57
% peak
160
175
190
–
10 Hz
–
1200
–
UI
775 Hz
14
–
–
UI
10 kHz - 100 kHz
0.4
–
–
UI
–
3
–
Hz
Jitter attenuation
–
50
–
db
Jitter attenuation tolerance before FIFO Overflow2
28
–
–
UI
Data decision threshold
Allowable consecutive zeros before LOS
Input jitter tolerance
Jitter attenuation curve corner frequency
1.
2.
3.
4.
5.
6.
22
4
Typical values are measured at 25 °C and are for design aid only; not guaranteed and not subject to production testing.
Not production tested but guaranteed by design and other correlation methods.
Input signal to TCLK is jitter-free.
Circuit attenuates jitter at 20 dB/decade above the corner frequency.
Referenced to power in 2 kHz band.
With a maximum of 6 dB of cable attenuation.
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
Figure 10. LXT300Z Typical Receive Jitter Tolerance
10000 UI
1200 UI
1000 UI
Jitter
138 UI
100 UI
LXT300Z Performance
Pub 62411
Dec 1990
28 UI
10 UI
G.823
Mar 1993
20
0.4 UI
0.2 UI
0.1 UI
1 Hz
10 Hz
1.2 UI
300
400
1.5 UI
1 UI
100 Hz
1 kHz
30 kHz
10 kHz
100 kHz
Frequency
Datasheet
23
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
Figure 11. LXT300Z Typical Receive Jitter Transfer Performance
20 dB
0.5 dB / 3 Hz
AT&T 62411 Template Slope
equivalent to 20 dB per decade
0.5 dB / 40 Hz
ITU G.735 Template Slope
equivalent to 20 dB per decade
0 dB
Gain
-10 dB
19.5 dB /
400 Hz
19.5 dB /
100 Hz
-20 dB
AT&T 62411 Template Slope
equivalent to 40 dB per decade
-30 dB
Typical LXT300Z Performance
-40 dB
20 Hz
1450 Hz
-60 dB
10 Hz
1 Hz
100 Hz
1 kHz
100 kHz
10 kHz
Frequency
Table 10. LXT300Z Receiver Timing Characteristics (See Figure 12)
Sym
Min
Typ1
Max
Units
RCLKd
40
-
60
%
DSX-1
tPW
–
324
–
ns
E1
tPW
–
244
–
ns
Parameter
Receive clock duty cycle
Receive clock pulse width2
RPOS/RNEG to RCLK rising
setup time
RCLK rising to RPOS/RNEG
hold time
DSX-1
tSUR
–
274
–
ns
E1
tSUR
–
194
–
ns
DSX-1
tHR
–
274
–
ns
E1
tHR
–
194
–
ns
Test Conditions
1. Typical values are at 25 °C and are for design aid only; they are not guaranteed and not subject to production testing.
24
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
Figure 12. LXT300Z Receive Clock Timing Diagram
tPW
tPWH
tPWL
tSUR
tHR
RCLK
RPOS
Host mode
CLKE = 1
RNEG
tSUR
tHR
RPOS
Host mode
RNEG
H/W mode
CLKE = 0, &
Table 11. LXT301Z Receive Timing Characteristics (See Figure 13)
Sym
Min
Typ1
Max
Units
DSX-1
RCLKd
40
50
60
%
E1
RCLKd
40
50
60
%
DSX-1
tPW
594
648
702
ns
Parameter
Receive clock duty cycle2
Receive clock pulse width2
E1
tPW
447
488
529
ns
DSX-1
tPWH
–
324
–
ns
E1
tPWH
–
244
–
ns
DSX-1
tPWL
270
324
378
ns
Test
Conditions
Receive clock pulse width High
Receive clock pulse width Low
E1
tPWL
203
244
285
ns
RPOS/RNEG to RCLK rising
setup time
DSX-1
tSUR
50
270
–
ns
E1
tSUR
50
203
–
ns
RCLK rising to RPOS/RNEG hold
time
DSX-1
tHR
50
270
–
ns
E1
tHR
50
203
–
ns
1. Typical values are at 25 °C and are for design aid only; they are not guaranteed and not subject to production testing.
2. RCLK duty cycle widths will vary depending on extent of received pulse jitter displacement. Max and Min RCLK duty cycles
are for worst case jitter conditions (0.4 UI clock displacement for 1.544 MHz, 0.2 UI clock displacement for 2.048 MHz).
Datasheet
25
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
Figure 13. LXT301Z Receive Clock Timing Diagram
tPW
tPWL
tPWH
tSUR
tHR
RCLK
RPOS
RNEG
Table 12. LXT300Z/301Z Master Clock and Transmit Timing Characteristics
(See Figure 14)
Parameter
Sym
Min
Typ1
Max
Units
DSX-1
MCLK
–
1.544
–
MHz
E1
MCLK
–
2.048
–
MHz
Master clock tolerance
MCLKt
–
±100
–
ppm
Master clock duty cycle
MCLKd
40
–
60
%
DSX-1
fc
–
6.176
–
MHz
E1
fc
–
8.192
–
MHz
DSX-1
TCLK
–
1.544
–
MHz
E1
TCLK
–
2.048
–
MHz
Master clock frequency
Crystal frequency
(LXT300Z only)
Transmit clock frequency
Transmit clock tolerance
TCLKt
–
±50
–
ppm
Transmit clock duty cycle
TCLKd
10
–
90
%
TPOS/TNEG to TCLK setup time
tSUT
25
–
–
ns
TCLK to TPOS/TNEG hold time
tHT
25
–
–
ns
1. Typical values are at 25 °C and are for design aid only; they are not guaranteed and not subject to production testing.
2. Not production tested but guaranteed by design and other correlation methods.
Figure 14. LXT300Z/301Z Transmit Clock Timing Diagram
TCLK
tSUT
tHT
TPOS
TNEG
26
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
Table 13. LXT300Z Serial I/O Timing Characteristics (See Figure 15 and Figure 16)
Parameter
Sym
Min
Typ1
Max
Units
Rise/fall time - any digital output
tRF
–
–
100
ns
SDI to SCLK setup time
tDC
50
–
–
ns
SCLK to SDI hold time
tCDH
50
–
–
ns
tCL
240
–
–
ns
SCLK Low time
tCH
240
–
–
ns
SCLK rise and fall time
tR, tF
–
–
50
ns
CS to SCLK setup time
tCC
50
–
–
ns
SCLK to CS hold time
tCCH
50
–
–
ns
CS inactive time
tCWH
250
–
–
ns
SCLK to SDO valid
tCDV
–
–
200
ns
SCLK falling edge or CS rising edge to SDO
high Z
tCDZ
–
100
–
ns
SCLK High time
Test Conditions
Load 1.6 mA, 50 pF
1. Typical values are at 25° C and are for design aid only; they are not guaranteed and not subject to production testing.
Figure 15. LXT300Z Serial Data Input Timing Diagram
CS
tCCH
tCH
tCC
tCL
tDC
tCDH
tCWH
SCLK
SDI
LSB
MSB
LSB
CONTROL BYTE
Datasheet
tCDH
DATA BYTE
27
LXT300Z/LXT301Z — Advanced T1/E1 Short-Haul Transceivers
Figure 16. LXT300Z Serial Data Output Timing Diagram
CS
tCDZ
SCLK
tCDV
tCDZ
HIGH Z
SDO
CLKE=1
tCDV
SDO
HIGH Z
CLKE=0
28
Datasheet
Advanced T1/E1 Short-Haul Transceivers — LXT300Z/LXT301Z
5.0
Mechanical Specifications
Figure 17. Package Specifications
28-pin Plastic Dual In-Line Package
Inches
• Extended Temperature Range (-40 °C to 85 °C)
• Part Number LXT300ZNE
• Part Number LXT301ZNE
E
1
E1
eA
eB
b2
D
A2
Millimeters
Dim
Min
Max
Min
Max
A
–
0.250
–
6.350
A2
0.125
0.195
3.175
4.953
b
0.014
0.022
0.356
0.559
b2
0.030
0.070
0.762
1.778
D
1.380
1.565
35.052
39.751
E
0.600
0.625
15.240
15.875
E1
0.485
0.580
12.319
14.732
e
1
1
0.100 BSC (nominal)
2.540 BSC (nominal)
eA
0.600 BSC1 (nominal)
15.240 BSC1 (nominal)
A
L
b
e
28-pin Plastic Leaded Chip Carrier
• Extended Temperature Range (-40 °C to 85 °C)
• Part Number LXT300ZPE
• Part Number LXT301ZPE
CL
C
B
eB
–
0.700
–
17.780
L
0.115
0.200
2.921
5.080
1. BSC—Basic Spacing between Centers.
Inches
Millimeters
Dim
Min
Max
Min
Max
A
0.165
0.180
4.191
4.572
A1
0.090
0.120
2.286
3.048
A2
0.062
0.083
1.575
1
2.108
1
B
.050 BSC (nominal)
1.27 BSC (nominal)
C
0.026
0.032
0.660
0.813
D
0.485
0.495
12.319
12.573
D1
0.450
0.456
11.430
11.582
F
0.013
0.021
0.330
0.533
1. BSC—Basic Spacing between Centers.
D1
D
D
A2
A
A1
F
Datasheet
29