
Keywords: LVDS SerializerDeserializer Performance over Twisted Pair Cable
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LVDS SerializerDeserializer Performance over Twisted Pair Cable
© May 13, 2003, Maxim Integrated Products, Inc.


A serializerdeserializer pair reduces interconnect wiring in highbandwidth, shortdistance data communications applications such as telecom and networking equipment backplanes, 3G cell phone basestation intrarack connections, and digital video interfaces. Currentmode LVDS signaling offers simplified termination, low transmission power, and low EMI.
The main LVDS standard, TIA/EIA644A, specifies physical layer parameters such as signal levels, but does not specify interconnect performance such as data rate versus cable length. The standard offers users the basic compatibility of LVDS signaling but needs to be supplemented in high data rate applications with information on attainable performance with a given cable type and length.
This article presents laboratory test results and analysis of the bit error ratio (BER) performance of the MAX9205/MAX9207 LVDS serializer and the MAX9206/MAX9208 deserializer at different data rates and cable lengths. This article also correlates BER with the jitter measured on link eye diagrams.
The Maxim MAX9205/MAX9207 LVDS serializer and MAX9206/MAX9208 LVDS deserializer are designed to transmit highspeed data over a serial pointtopoint link with 100Ω differential characteristic impedance. The serial "payload" data rate (with overhead synchronization bits excluded) is 160Mbps to 400Mbps for the MAX9205–MAX9206 pair and 400Mbps to 600Mbps for the MAX9207–MAX9208 pair. Both have the same pinout and but each pair is optimized for operation over a different frequency range. The BER and eye diagram jitter using unshielded twisted pair CAT5E cable of various lengths is investigated.
To measure the reliability of a link, the BER test is the most straightforward and accurate measure. Digital communication links require very low error ratios on the order of one error in one hundred billion received bits (BER of 10
^{12}) or less.
However, to make a BER test, a high performance signal generator and specialized test equipment are needed, and the BER test is time consuming. Depending on the transmission rate, it can take hours or even days to transfer the number of bits required to test for a BER of 10
^{12} or less. Due to the time consuming nature of a BER test, faster measures are commonly employed to predict link reliability. One is to establish jitter levels that produce a low BER. Jitter for the MAX9205–MAX9206 and MAX9207–MAX9208 links (termed "marginal jitter" in
Figure 3) is measured and correlated to BER. The BER test is used to validate the datasheet jitter maximum values.
Test Setup
The LVDS signal is transmitted by the MAX9205 or MAX9207 LVDS serializer. The serializer latches 10 bits of parallel data on the rising edge of the parallel data clock (TCLK), adds two overhead synchronization bits and transmits the serialized data through a single LVDS output. The parallel data clock range is 16MHz to 40MHz for MAX9205 and 40MHz to 60MHz for MAX9207. With the two synchronization bits included, the serial bit rate is 12 × TCLK. The "payload" serial data rate (serial bit rate minus the two synchronization bits) is 10 × TCLK. The functional blocks of MAX9205/MAX9207 and MAX9206/MAX9208 are shown in
Figure 1.
Figure 1. Serializer and deserializer functional block diagram.
In the cable test setup (
Figure 2) the serializer and deserializer on evaluation board number two are used to convert the serial I/O of the Agilent 86130A BER tester to parallel. The parallel data is applied to and read from cable test evaluation board number one. The serial data sequence output by the 86130A is 1200 bits long and is generated by taking 1000 bits from a PRBS of 2
^{10}1 and inserting "01" synchronization bits every 10 PRBS bits. Insertion of the synchronization bits mimics the bits that would be added by a serializer. The deserializer on board two removes the synchronization bits and presents the PRBS data in parallel to the cable test serializer on board one. The serial data sequence is repeated continuously. The Agilent 81250 generates the required reference clocks (TCLK for the serializer and REFCLK for the deserializer). The cable is Ethernet Category 5E, AWG24, unshielded twisted pair manufactured by General Cable Inc. (part number 2133629H).
Figure 2. Cable test setup.
The BER was tested using cable lengths of 5ft, 15ft, 30ft, 60ft and 100ft. Eye diagram jitter was measured at the deserializer input using a Tektronix TDS784C oscilloscope and Tektronix P6247 1.0GHz differential probe. The delays of the TCLK serializer reference clocks generated by the 81250 were adjusted to meet the serializer input setup and hold time requirements as listed in the datasheet.
Measurements and Results
Tests were conducted separately for MAX9205–MAX9206 and MAX9207–MAX9208 serializerdeserializer pairs. The serial bit rate generated by the 86130A was 192Mbps–480Mbps for the MAX9205–MAX9206 and 480Mbps–720Mbps for the MAX9207–MAX9208.
To quantify eye diagram signal integrity, two parameters are defined; total jitter t
_{TJ} and marginal jitter t
_{MJ}. t
_{TJ} is the width of the timing jitter measured at zero differential voltage (zero differential voltage is the main horizontal graticle in the oscilloscope plots). t
_{MJ} is the time measured from the center of the jitter at zero differential voltage to 300mV peaktopeak differential voltage (see
Figure 3). The deserializer differential input can be roughly assumed to switch at zero volts differential but it is more conservative to assume additional differential voltage to provide the needed overdrive. t
_{TJ} assumes switching at zero volts differential but t
_{MJ} requires the differential signal to reach 300mV
_{PP} before it is considered to have switched the deserializer input. t
_{MJ} is therefore a more conservative measure of signal integrity. t
_{UI} (also Figure 3) is defined as the duration of a serial bit (unit interval). The unit interval is the period of the reference frequency divided by 12.
The differential peaktopeak voltage is denoted as V
_{PP}. V
_{PP} is two times the magnitude of the difference of the singleended voltages at the measurement point, or V
_{PP} = 2 × (V
_{OUT+})  (V
_{OUT}). For example, at the measurement point, if V
_{OUT+} = 1.35V and V
_{OUT} = 1.10V relative to ground in the high state and V
_{OUT+} = 1.10V and V
_{OUT} = 1.35V relative to ground in the low state, then V
_{PP} = 500mV. Since the measurements are made with a differential probe (which subtracts V
_{OUT} from V
_{OUT+}) the eye diagrams show V
_{PP}.
Figure 3. Jitter measurement definitions.
Table 1 shows the maximum values of t
_{MJ} as specified in the MAX9206/MAX9208 deserializer datasheet. The deserializer is guaranteed to recover data if t
_{MJ} is less than or equal to the listed maximum.
Table 1. Datasheet Maximum Marginal Jitter
Bit
Rate (Mbps)

Data
Rate
(Mbps)

Maximum
Marginal
Jitter t_{MJ} (ps)

192

160

1300

480

400

720

720

600

320

Testing was conducted under two conditions. Under the first condition, t
_{TJ}, and t
_{MJ} were measured and bit errors counted while running the serial test pattern for one hour for each cable length at the highest data rate allowed for the serializer—deserializer pair under test. Under the second condition, the serial test data was transmitted for more than 10 hours (transmitting more than 1.73 × 10
^{13} bits) under conditions of high jitter such that maximum datasheet values for t
_{MJ} were exceeded. t
_{TJ}, and t
_{MJ} were measured and bit errors counted.
Tables 2 and
3 show test results for cable lengths from 5ft to 60ft for the MAX9205–MAX9206 and MAX9207–MAX9208 serializerdeserializer pairs. The bit rate is the serial signaling rate and the data rate is the "payload" serial data rate (data rate = (10/12) × bit rate).
Table 2. MAX9205–MAX9206 t_{TJ}, t_{MJ}, V_{PP} and Bit Errors (Measured for One Hour)
Cable
Length
(Feet)

Bit
Rate
(Mbps)

Data
Rate
(Mbps)

Total
Jitter
t_{TJ} (ps)*

Marginal
Jitter
t_{MJ} (ps)*

Differential
Voltage
V_{PP} (mV*)

Error
Count (1.728 x 10^{12} bits)

5

480

400

200

220

880

No Error

15

480

400

200

260

780

No Error

30

480

400

220

320

636

No Error

60

480

400

360

560

420

No Error

*Measurement resolution for t
_{TJ}, t
_{MJ} is 10ps. Measurement resolution for V
_{PP} is 2mV.
Table 3. MAX9207–MAX9208 t_{TJ}, t_{MJ}, V_{PP} and Bit Errors (Measured for One Hour)
Cable
Length
(Feet)

Bit
Rate
(Mbps)

Data
Rate
(Mbps)

Total
Jitter
t_{TJ} (ps)*

Marginal
Jitter
t_{MJ} (ps)*

Differential
Voltage
V_{PP} (mV*)

Error
Count (2.592 x 10^{12} bits)

5

720

600

180

200

852

No Error

15

720

600

180

230

660

No Error

30

720

600

220

270

556

No Error

60

720

600

320

N/A
(V_{PP }< 300mV)

292

No Error

*Measurement resolution for t
_{TJ}, t
_{MJ} is 10ps. Measurement resolution for V
_{PP} is 2mV.
As test examples,
Figure 4 shows eye diagrams taken at the MAX9208 deserializer input after 30ft and 60ft of cable.
Figure 4a. MAX9207–MAX9208 Eye diagram with 30ft cables.
30ft, 720Mbps, t_{TJ}=220ps, t_{MJ} = 270ps, 2.592 × 10^{12} bits transmitted.
No errors. Vertical scale: 200mV/Div. Horizontal scale: 500ps/Div.
Figure 4b. MAX9207–MAX9208 Eye diagram with 60ft cables.
60ft, 720Mbps, t_{TJ}=320ps, t_{MJ} = N/A, 2.592 × 10^{12} bits transmitted.
No errors. Vertical scale: 200mV/Div. Horizontal scale: 500ps/Div.
To demonstrate the capability of the deserializer to recover data under degraded signal conditions (that is, with less jitter margin than specified in the datasheet) tests were conducted for both serializerdeserializer pairs using 100 feet of cable. The serial test data was transmitted continuously for more than 10 hours.
Table 4 shows the measurements of jitter, peakpeak voltage, and error counts.
Figure 5 provides the eye diagram plots.
Table 4. MAX9205–MAX9206 and MAX9207–MAX9208 t_{TJ}, t_{MJ}, V_{PP} and Bit Errors
Cable
Length
(Feet)

Bit
Rate
(Mbps)

Data
Rate
(Mbps)

Total
Jitter
t_{TJ} (ps)*

Marginal
Jitter
t_{MJ} (ps)*

Differential
Voltage
V_{PP} (mV*)

Error
Count (2.592 x 10^{12} bits)

MAX9205–MAX9206

100

480

400

660

N/A

192

Transmitted bits:
1.73 x 10^{13}
Error bits: 0
Test time:
> 10hrs

MAX9207–MAX9208

100

520

433

1020

N/A

110

Transmitted bits:
1.87 x 10^{13}
Error bits: 0
Test time:
> 10hrs

*Measurement resolution for t
_{TJ}, t
_{MJ} is 20ps. Measurement resolution for V
_{PP} is 2mV.
Figure 5a. Eye Diagram with 100ft Cables.
100ft, 480Mbps, t_{TJ}=660ps, t_{MJ} = N/A, 1.73 × 10^{13} bits transmitted.
No errors. Vertical scale: 200mV/Div. Horizontal scale: 1ns/Div.
Figure 5b. Eye Diagram with 100ft Cables.
100ft, 520Mbps, t_{TJ}=1020ps, t_{MJ} = N/A, 1.87 × 10^{13} bits transmitted.
No errors. Vertical scale: 200mV/Div. Horizontal scale: 1ns/Div.
No bit errors are recorded in any of the tests. After 100 feet of cable at a bit rate of 520Mbps, the amplitude of the signal is 110mV. This is approximately one third of the 300mV
_{PP} amplitude specified for t
_{MJ}. Also, with t
_{TJ} = 1020ps, over half the 1923ps unit interval (t
_{UI} = 1/520Mbps) is jitter. The errorfree test result under these conditions provides a measure of the margin in the datasheet specifications (Table 1).
Also, based on the test results, the BER can be predicted. Assume that the probability of error for any bit in the serial data sequence is the same and the error events are independent among the bits. If the BER is q, then the serial data sequence can be modeled as Bernoulli trials with parameter q. Assuming n is the number of bits transmitted, then probability of an nbit sequence with no error can be expressed as
P_{no error} = (1  q)^{n} 
Eq. 01

With 100 feet of cable more than 1.73 × 10
^{13} were transmitted with no error. If we assume that the BER value q is less than 3.01 × 10
^{13}, then P
_{no error} given by Eq. 01 is 0.0056. This can be interpreted as if the BER has a value of 3.0 × 10
^{13} or bigger, the probability of no error occurring for an observed bit sequence of 1.73 × 10
^{13} is 0.0056. In terms of statistics, if a sequence of 1.73 × 10
^{13} bits are transmitted without error the hypothesis of BER < 3.0 × 10
^{13} is 99.44% correct. Since this confidence is obtained with 100 feet of cable and poor signal quality, shorter cable lengths and better signal quality will produce better confidence in the link reliability.
Conclusion
Using the BER test, this article has examined the reliability of MAX9205–MAX9206 and MAX9207–MAX9208 serializerdeserializer pairs over low cost CAT5E cables of various lengths. The results have shown that even with severe signal degradation the link BER is less than 3.0 × 10
^{13} with more than 99% confidence. The results also demonstrate that the datasheet jitter maximum limits are sufficient and conservative for high link reliability. Since the measurements were conducted under typical conditions, it is recommended that the criterion in Table 1 be used for real applications. This provides margin to compensate for variations in fabrication, supply voltage, and temperature.
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APP 2023: May 13, 2003
APPLICATION NOTE 2023,
AN2023,
AN 2023,
APP2023,
Appnote2023,
Appnote 2023
