ETC LXT380/LXT381

LXT380/1
Frequently Asked Questions
January 2001
Order Number: 249181-001
As of January 15, 2001, this document replaces the Level One document known as LXT380/LXT381FAQs.
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Frequently Asked Questions
LXT380/1
Contents
1.0
Questions and Answers .......................................................................................... 5
1.1
1.2
1.3
1.4
1.5
Microprocessor Interface....................................................................................... 5
Line Interface......................................................................................................... 6
Digital (Framer) Interface ....................................................................................11
JTAG Port............................................................................................................12
General Questions ..............................................................................................13
1
2
Receive Interface .................................................................................................. 8
Transmit Interface .................................................................................................9
Figures
Frequently Asked Questions
3
LXT380/1
4
Application Note
LXT380/LXT381
1.0
Questions and Answers
1.1
Microprocessor Interface
Q1.
In Motorola Mode, can I connect CS and DS together ?
Yes. Our timing specifications allow you to connect these signals together. There is no
delay specified between CS and DS.
Q2.
I’m using the LXT380 in the non-multiplexed Motorola mode. What should I do with
the address strobe signal (AS) ?
In non multiplexed Motorola mode there is no need for an address strobe signal. Therefore
should be pulled High.
Q3.
In non-multiplexed Intel mode what do I do with the ALE signal?
In non multiplexed Intel mode there is no need for an address latch enable signal. Therefore
ALE should be pulled High.
Q4.
What is the maximum bus speed the LXT380 can operate at?
The designer should refer to the LXT380 data sheet for timing specifications. Comparing
the minimum signal widths with the corresponding microprocessor bus signals will
determine if the devices can be connected directly. For extremely fast microprocessors, the
LXT380 supports wait-state generation through the ACK / RDY (Motorola/Intel) pin.
Q5.
How to handle an Interrupt in the Interrupt Service Routine ?
In the LXT380 there are three kinds of registers associated with interrupt handling:
interrupt enable registers, interrupt status registers and status registers.
Writing a “1” into an interrupt enable register will enable the corresponding interrupt for
the respective channel. For example, if LIE = FFh (LOS Interrupt Register) then loss of
signal interrupts will be enabled for all eight channels.
The interrupt status registers signal that an interrupt was caused by a change in status in the
corresponding channel. For example, if an interrupt is triggered by a loss of signal in
channel 0, the associated interrupt service routine will start by reading the interrupt status
registers in order to identify the cause for the interrupt. In this example you should read LIS
= 01h (LOS Interrupt Status Register).
After reading the interrupt status register the software will read the associated status register
to monitor the current status and take appropriate action. If in the example above, the loss
of signal condition is still valid at the time the register is read then LOS = 01h (LOS Status
Monitor Register). By reading the status register the interrupt condition will be cleared.
The following picture illustrates the interrupt handling process:
Frequently Asked Questions
5
LXT380/LXT381
Enable Interrupts
Does an Interrupt
Condition Exist ?
Read Interrupt Status
Register
Read Corresponding
Status Register
Service the Interrupt
1.2
Line Interface
Q6.
Can I use the same transformer (1:2) for the transmit and receive side?
Yes. The receiver sensitivity of the LXT380/1 is high enough to accommodate the loss
introduced by a 2:1 step-down transformer. Our lab tests indicate that this configuration
will reduce the maximum cable sensitivity by approximately 2dB @ 1.024MHz. This
means a maximum cable attenuation of 10dB which is well above the required 6dB
minimum for ITU-T G.703 compliance.
Note that the receive terminating resistors (RR in the data sheet) should be scaled
appropriately to 9.31ohm and 15.0 ohm for coaxial cable and twisted pair cable
respectively.
6
Frequently Asked Questions
LXT380/LXT381
Q7.
What transformers should I use with the LXT380/1?
Transformer specifications for the LXT380/1 are listed in the data sheet (LXT380 see Table
40 and LXT381 see Table 10). Any transformer that meets these specifications can be used
with the LXT380/1. The following table contains examples of transformers recommended
by Intel:
Manufacturer
Halo Electronics
Part Number
TG49 - LVL1NX
TG49 - 1505NX
TG48 - 1205N1
TG29 - 1205NX
TG26 - 1205N1
TD26 - 1505D
Pulse Engineering
T1124 / T1114
T1066 / T1106
T1068 / T1168
T1065 / T1105
PE - 68678
PE - 68877
PE - 68841
PE - 68861
Bell Fuse
S553-6500-55
S553-6500-37
S553-6500-10
PCA Electronics
Frequently Asked Questions
EPA3557S
Channels
Turns Ratio
4Tx,
1CT:2 Tx
4Rx
2CT:1 Rx
4Tx,
1CT:2 Tx
4Rx
2CT:1 Rx
1Tx,
1CT:2CT Tx
1Rx
1:1 Rx
4Tx,
1:2 Tx
4Rx
2CT:1 Rx
1Tx,
1CT:2CT Tx
1Rx
2CT:1CT Rx
1Tx,
1:2CT Tx
1Rx
1:2CT Rx
4Tx,
1CT:2 TX
4Rx
2CT:1 Rx
4Tx,
1:2 Tx
4Rx
1:2CT Rx
4Tx,
1:2CT Tx
4Rx
1:1CT Rx
4Tx,
1:2CT Tx
4Rx
1:2CT Rx
1Tx,
1CT:1CT Rx
1Rx
1CT:2CT Tx
1Tx,
1CT:1CT Rx
1Rx
1CT:2CT Tx
1Tx,
1CT:2CT Rx
1Rx
1CT:2CT Tx
1Tx,
1CT:2CT Rx
1Rx
1CT:2CT Tx
4Tx,
1CT:2 Tx
4Rx
2CT:1 Rx
4Tx,
1CT:2 Tx
4Rx
2CT:1 Rx
1Tx,
1CT:2CT Tx
1Rx
1CT:2CT Rx
4Tx,
1CT:2 Tx
4Rx
2CT:1 Rx
SMD
Temperature Range
Yes
EXT Temp
Yes
EXT Temp
Yes
STD Temp
Yes
STD Temp
Yes
STD Temp
No
STD Temp
Yes
Yes
Yes
Yes
T1124 - STD Temp
T1114 - EXT Temp
T1066 - STD Temp
T1106 - EXT Temp
T1068 - STD Temp
T1168 - EXT Temp
T1065 - STD Temp
T1105 - EXT Temp
Yes
STD Temp
Yes
EXT Temp
Yes
EXT Temp
Yes
STD Temp
Yes
EXT Temp
Yes
EXT Temp
Yes
STD Temp
Yes
STD Temp
7
LXT380/LXT381
Q8.
How can I support E1 75/120 ohm operation in the same design?
The following figure suggests a configuration for the receive side. The relay RL2 selects
the appropriate terminating impedance (75 or 120 ohm). Relay RL1 is needed to isolate the
balanced interface from the earth connection of the coaxial interface. If the connection
through JP1 is made, connecting both signals together would ground (unbalance) one of
the balanced output signals. The connection to earth through JP1 is provided in accordance
to G.703. This connection should only be removed when earth currents interfere with
normal operation.
Figure 1. Receive Interface
RL2
TWP
Coax
1:1
1KΩ
Coax
75 Ω
RTIP
60.4Ω
LXT380/1
200 Ω
0.22uF
33 nF
JP1
60.4Ω
RRING
1KΩ
RL1
Twisted Pair
120 Ω
The following figure suggests a configuration for the transmit side. Since the LXT380/1
uses the same resistor/transformer combination for both 75 ohm and 120 ohm the design is
simplified. The connection to earth through JP1 is recommended for G.703 compliance.
8
Frequently Asked Questions
LXT380/LXT381
Figure 2. Transmit Interface
TVCC
D4
11Ω
1:2
TTIP
Coax
75 Ω
D3
560pF
LXT380/1
33 nF
TVCC
JP1
D2
TRING
D1
11Ω
RL1
Twisted Pair
120 Ω
Q9.
Does the LXT380/1 meet G.703 Annex B protection requirements?
Yes, when used with the recommended transmit and receive interface described in the data
sheet. The recommended interface includes protection elements that ensure G.703 Annex
B compliance at a minimum cost. Refer to Application Note 106 for more details.
Q10.
I’m only using 7 channels in my design. What should I do to the TIP and RING signals
in the unused channel?
The unused TTIP and TRING pins should be left open. The unused RTIP and RRING pins
should be connected together through a capacitor or 1kW resistor to avoid noise coupling
into the device. Do not connect RTIP/RRING to ground since these signals have a 2.0 V
biasing voltage.
Q11.
How should I adjust the 560 pF capacitor in the transmit interface?
The main purpose of the transmit 560 pF capacitor is to slightly increase the high frequency
transmit return loss. Typical applications already have a substantial amount of parasitic
capacitance. Sources of parasitic capacitance are the protection elements, common mode
chokes, long PCB traces and connectors. Too much capacitance might cause some slight
ringing in the output pulse. In these cases, the designer is advised to reduce the capacitor
value. However, for most designs, a 560pF capacitor provides good results.
Q12.
Does the LXT380/1 meet BS5450 50 mArms output short-circuit current limitation?
Yes. The following figure represents a simplified Thevenin equivalent for the LXT380/1
transmit interface with a short-circuit at the output:
Frequently Asked Questions
9
LXT380/LXT381
I1
11Ω
1:2
2.6 Vpk
I2
11Ω
I1 can be approximated as:
I1pk = 2.6 / (2x11) = 118 mA pk
The worst-case short-circuit current occurs when an all ones is being transmitted. For an E1
all ones signal, the rms current can be calculated as:
I1rms = I1pk / ÷2 = 84 mA rms
I2rms = I1rms / 2 = 42 mA rms < 50 mA rms
Therefore, the worst case short-circuit current will be always less than 50 mA rms. Note,
for simplicity, these calculations ignore the effect of the transformer winding resistance and
driver output impedance. The actual short circuit current should be even lower than
calculated.
Q13.
How do I tri-state the LXT380/1 output drivers?
The output driver tri-state capability is useful in designing protection systems without
external relays. For details on implementing redundancy applications without relays please
refer to Application Note AN119.
The LXT380/1 offers two distinct methods for tri-stating the output drivers.
Hold the corresponding channel’s TCLK Low for at least 8ms. This method allows driver
tri-stating on a per-channel basis.
Set the OE pin Low to tri-state all the output drivers. The OE pin in the LXT380/1 allows
fast switching between redundant and working boards without having to individually tristate every output driver.
Q14.
10
What are the layout recommendations for the analog interface?
Here’s a list of general guidelines for the analog T1/E1 interfaces:
•
Place decoupling capacitors very close to the corresponding TVCC/VCC pins.
•
Avoid crossing transmit and receive signals to minimize cross-talk.
•
Avoid routing digital signals near analog signals (TIP/RING) and receiver inputs.
•
Provide ample power and ground planes.
Frequently Asked Questions
LXT380/LXT381
• Route differential pairs like RTIP/RRING and TTIP/TRING close together. Make sure
the trace length for differential signals is about the same.
• Don’t extend the ground plane beyond the line side of the transmit and receive
transformers. Ground plane noise could be coupled into the line signals increasing RF
emissions.
•
Minimize trace lengths connecting the LIU to transformers and connectors.
• When using surge protection elements in the line side of the transformer such as TVS,
place them as close as possible to the disturbance source, i.e., the connector.
1.3
Digital (Framer) Interface
Q15.
How do RPOS/RNEG behave upon loss of signal (LOS) ?
RPOS and RNEG will output the data content as seen at the line input. If LOS is caused by
a total signal failure (all zeros), RPOS/RNEG will be Low all the time. However, if there
are occasional 1’s, they will be seen at RPOS/RNEG. This allows the framer or mapper
connected to the LXT380 to perform LOS detection and LOS reset based on the RPOS/
RNEG output.
Q16.
How do I interface the LXT380/1 with 5V logic?
The following figure contrasts the 3.3V and 5.0V I/O configurations. 5V I/O capability is
accomplished by connecting the 5V power supply to the VCCIO pins. Note that the power
to the internal logic (VCC pins) and output drivers (TVCC pins) must still come from a
3.3V supply.
The outputs from the LXT380/1 will be 5V when VCCIO pins = 5V. Therefore, the devices
that interface with the LXT380/1 must be 5V tolerant. Naturally, 5V devices have 5V
tolerant inputs.
+3.3V
Output can be 3.3 V
or 5V
IN
Input can be 5V or
3.3V
IN
LXT380/1
OUT
Frequently Asked Questions
VCCIO
VCCIO
Output must be
3.3 V
+5V
Input must be 5V
tolerant
LXT380/1
OUT
11
LXT380/LXT381
Q17.
What is the difference between Unipolar and Bipolar mode operation?
Bipolar and unipolar modes are two different ways for an LIU to interface to a framer or
back end ASIC. The following is from the receive perspective. The transmit perspective is
similar.
The T1 or E1 data (zeros and ones) is coded as alternate positive and negative pulses for
signaling logic 1’s on the line. Zeros are coded as a zero voltage.
In bipolar mode, two data lines, (RPOS and RNEG) plus a clock line (RCLK) connect the
LIU to the framer. A logic "1" on RPOS tells the framer that a positive pulse was detected
on the line. A logic "1" on RNEG tells the framer that a negative pulse was detected on the
line. In bipolar mode, it’s the framer’s responsibility to decode the sequence of positive and
negative pulses into a sequence of logic zeros and ones. This is done by the AMI or B8ZS/
HDB3 decoders inside the framer.
In unipolar mode, only one data line (RDATA) plus a clock (RCLK) connect the LIU to the
framer. The sequence of positive and negative pulses is decoded inside the LIU. The
resulting sequence of zeros and ones is output on TDATA. In unipolar mode, the AMI or
B8ZS/HDB3 decoders are automatically enabled inside the LIU.
Typically, the LIU also provides a BPV (bipolar violation) output when in unipolar mode.
This output indicates the reception of positive / negative pulse sequences that do not respect
the selected encoding scheme (AMI, B8ZS/HDB3). Noise or cross talk on the line may
trigger such violations of the encoding scheme. Some framers provide a BPV input that will
drive internal BPV counters for performance monitoring purposes.
In bipolar mode, the BPVs are detected inside the framer based on the positive/negative
pulse sequence in RPOS/RNEG.
1.4
JTAG Port
Q18.
Q19.
12
Where can I get the BSDL files for the JTAG interface ?
The BSDL files for the LXT380 can be found
www.developer.intel.com/design/network.
on
Intel’s
website
at
How can I use the Analog JTAG port to test my metallic Tx/Rx interfaces ?
The analog JTAG functionality is illustrated in the following diagram:
Frequently Asked Questions
LXT380/LXT381
JTAG Port
ASR Register
RTIP7
Transceiver 7
RRING7
TTIP7
TRING7
TTIP6
TRING6
1K
Analog Mux
RTIP6
RRING6
Transceiver 6
RTIP0
RRING0
Transceiver 0
1K
AT2
AT1
The AT1 and AT2 pins are the analog test port input and output respectively. A voltage can
be forced into any of the TTIP or RTIP pins. The voltage at the corresponding TRING or
RRING pin is output at AT2. The selection is made by setting the ASR register in the JTAG
interface.
If the connections across the primary transformer windings are good, there should be a total
impedance of approximately 2 k ohm (DC) in the receive path (2 x 1 k ohm) and
approximately 22 ohm (2 x 11 ohm) across the transmit path. If the impedance is much
higher than the expected value, there may be an open circuit in the path (possibly caused by
a bad component or soldering problem). As you can see, this feature allows testing the
analog interface connections. This is something that is not possible with conventional
(digital) JTAG interfaces.
1.5
General Questions
Q20.
What are the main differences between the LXT381 and the LXT380?
The LXT381 features can be seen as a subset of the LXT380. The main differences are:
• The LXT381 is a data recovery only device.
•
The LXT381 is controlled by hardware only.
Frequently Asked Questions
13
LXT380/LXT381
•
The LXT381 does not support G.772 monitoring.
The LXT381 provides the essential analog front-end features. It is intended for applications
where the back-end ASIC implements most of the digital features such as clock recovery
alarm processing.
The LXT380, with its rich set of features, is ideal for interfacing with standard framers or
mappers requiring external clock recovery.
Q21.
What is the maximum jitter allowed on MCLK?
MCLK is used internally as a reference for the clock recovery DPLLs. We strongly
recommend a jitter free, independent MCLK clock from a crystal oscillator. Any jitter
present at MCLK will be added to the RCLK output almost transparently. The designer
should decide the maximum output jitter that can be tolerated at the output which is based
on the specifications the equipment is to comply with.
Q22.
Where can I get the IBIS models for the LXT380/1 ?
The IBIS models for the LXT380 can be found
www.developer.intel.com/design/network.
on
Intel’s website at
Q23.
How much power is dissipated in the LXT380/1 package?
The maximum power dissipated in the package can be found under "Absolute Maximum
Ratings", Table 26 and is equal to 850 mW. Do not use the maximum power supply current
and power supply voltage values to derive the power dissipated in the package. A good
percentage of the power consumed by the LIU is delivered to the E1 line. This power is
dissipated outside the LIU package.
Q24.
How does the G.772 monitoring work?
The LXT380 can be configured as an octal line interface unit with all channels working as
regular transceivers. In applications using only seven channels, the eighth channel can be
configured to monitor any of the remaining channel’s inputs or outputs.
The monitoring is non-intrusive per ITU-T G.772. The following figure illustrates this
concept.
14
Frequently Asked Questions
LXT380/LXT381
MODE
JTAG
CONTROL
INTERFACE
SERIAL/
PARALLEL PORT
MCLK
CLKE
Transceiver 7
LOS7
G.775
LOS
RRING7
TTIP7
Data Clock
Recovery
Line Driver
Pulse
Shaper
Digital Loopback
Analog Loopback
RTIP7
Remote Loopback
Data Slicer
TRING7
RPOS7
RCLK7
RNEG7
LOOP7
TPOS7
TCLK7
TNEG7
LOS6
RTIP6/RRING6
RPOS6/RNEG6/RCLK6
Transceiver 6
TPOS6/TNEG6/TCLK6
TTIP6/TRING6
LOOP 6
LOS5
RTIP5/RRING5
Transceiver 5
RPOS5/RNEG5/RCLK5
TPOS5/TNEG5/TCLK5
TTIP5/TRING5
TTIP4/TRING4
RTIP3/RRING3
TTIP3/TRING3
RTIP2/RRING2
G.772 Protected Monitoring Point
RTIP4/RRING4
LOOP 5
LOS4
Transceiver 4
RPOS4/RNEG4/RCLK4
TPOS4/TNEG4/TCLK4
LOOP 4
LOS3
Transceiver 3
RPOS3/RNEG3/RCLK3
TPOS3/TNEG3/TCLK3
LOOP 3
LOS2
Transceiver 2
RPOS2/RNEG2/RCLK2
TPOS2/TNEG2/TCLK2
TTIP2/TRING2
LOOP 2
RTIP1/RRING1
LOS1
Transceiver 1
RPOS1/RNEG1/RCLK1
TPOS1/TNEG1/TCLK1
TTIP1/TRING1
LOOP 1
Transceiver 0
G.775
LOS
LOS0
TTIP0/MOP
TRING0/MON
A3 - A0
Data Clock
Recovery
Line Driver
Pulse
Shaper
Digital Loopback
RRING0
MUX
Remote Loopback
RTIP0
Analog Loopback
Data Slicer
RPOS0
RCLK0
RNEG0
LOOP0
TPOS0
TCLK0
TNEG0
The monitored line signal (input or output) goes through channel 0 clock and data recovery.
The signal can be observed digitally at the RCLK/RPOS/RNEG outputs. This feature can
also be used to create timing interfaces derived from an E1 signal. Please refer to
Application Note 249128: “Timing Interface Using the LXT380".
Frequently Asked Questions
15
In addition, channel 0 can be configured for Remote Loopback while in monitoring mode.
This will output the same data as the signal being monitored at the channel 0 output (TTIP/
TRING). The output signal can then be connected to standard test equipment with an E1
electrical interface for monitoring purposes (non -intrusive monitoring).