dta-sdh/155 operating manual · 2018-03-19 · dta-sdh/155 operating manual shineway technologies,...

DTA-SDH/155 Operating Manual

Copyright © 2014, Shineway Technologies, Inc.

All rights reserved


Shineway Technologies, Inc. 2

1. Instrument Profile ............................................................................................................................... 4

1.1. Physical Characteristics .......................................................................................................... 4 1.2. Introduction to Graphical User Interface ................................................................................. 7

2. Test Configuration .............................................................................................................................. 8 2.1. Test Mode ................................................................................................................................ 9

2.1.1. SDH Path Mode (Default Mode of the Manufacturer) .................................................... 10

2.1.2. SDH Demux Mode .............................................................................................................. 10

2.1.3. SDH Mux Mode ................................................................................................................... 10

2.1.4. SDH Monitor Mode .............................................................................................................. 11

2.1.5. SDH Through Mode ............................................................................................................ 11

2.1.6. PDH Path Mode ................................................................................................................... 11

2.1.7. PDH Monitor Mode .............................................................................................................. 11

2.1.8. PDH Span Mode .................................................................................................................. 12

2.1.9. PDH Through Mode ............................................................................................................ 12 2.2. Parameter Setup ................................................................................................................... 12

2.2.1. Physical Interface ................................................................................................................ 12

2.2.2. Receiving Gain .................................................................................................................... 13

2.2.3. Mapping ................................................................................................................................ 13

2.2.4. PRBS Code Pattern ............................................................................................................ 14

2.2.5. Transmission Clock ............................................................................................................. 14 2.3. LED Interface ........................................................................................................................ 15

2.3.1. SDH Interface ...................................................................................................................... 15

2.3.2. TCM Interface ...................................................................................................................... 17 3. Error Performance Analyzer ............................................................................................................. 18

3.1. Tests Summary ...................................................................................................................... 19 3.2. Error Test Result .................................................................................................................... 19 3.3. Error Performance Analyser .................................................................................................. 20

3.3.1. SDH Part ............................................................................................................................... 20

3.3.2. PDH Part ............................................................................................................................... 21 4. Event Record.................................................................................................................................... 24

4.1. Trace Overhead Test ............................................................................................................. 24 4.2. Regular Overhead Test ......................................................................................................... 25 4.3. Pointer Value Test ................................................................................................................. 25 4.4. Pointer Sequences Test ........................................................................................................ 26 4.5. Error Insert Test ..................................................................................................................... 27 4.6. Insert Alarm ........................................................................................................................... 28 4.7. Pointer Adjusting Test ............................................................................................................ 28

5. Function Test .................................................................................................................................... 30 5.1. APS Test ................................................................................................................................ 30 5.2. Data Path (Transparency) Test ............................................................................................. 31 5.3. TCM Test ............................................................................................................................... 31 5.4. RTD Test ................................................................................................................................ 32 5.5. Tributary Scan Test ............................................................................................................... 33

6. Test Result ........................................................................................................................................ 34 6.1. Alarm Test Result .................................................................................................................. 34 6.2. Error Code Test Result .......................................................................................................... 35 6.3. Pointer Test Result ................................................................................................................ 35 6.4. Overhead Test Result ............................................................................................................ 36 6.5. TCM Test Result .................................................................................................................... 37 6.6. Data Path Test (Transparency) Result .................................................................................. 37 6.7. Frequency Test Result .......................................................................................................... 38 6.8. Tributary Test Result ............................................................................................................. 38

7. System Setup ................................................................................................................................... 40 7.1. File Management .................................................................................................................. 40

7.1.1. Configuration File: ............................................................................................................... 40

7.1.2. Result File ............................................................................................................................. 41



7.2. Version Information ............................................................................................................... 41 7.3. Recover Default..................................................................................................................... 42 7.4. Time Setup ............................................................................................................................ 42 7.5. Touch Screen Calibration ...................................................................................................... 42 7.6. Other Setup ........................................................................................................................... 43 7.7. Performance Objectives ........................................................................................................ 43 7.8. USB Connection .................................................................................................................... 44



1. Instrument Profile

1.1. Physical Characteristics

This chapter introduces various major parts of DTA-SDH/155 so that you can know the appearance

Top

Figure 1-1 DTA-SDH/155 Profile

and overall structure of the instrument. Façade



Figure 1-2 Top View

(1) Electrical adapter port;

(2) BNC input joint for external clock;

(3) Standard USB port;

(4) BNC joint of output port;

(5) BNC joint of input port;

(6) SFP port for opticalinput/output.



Figure 1-3 Façade View

(1) Fastening metal buckle of the belt;

(2) Color LCD screen;

(3)LED pointer light; ：Instrumentation Power on instructions; ：Instrumentation external

power supply instructions;

Note: In order to ensure the performance and battery life, please use the first three put the

battery completely discharge and recharge 12-14 hours, After 4-6 hours per charge achieved.

(4) Keypad: keys can be used for operation in case of the failure of touch screen.



Figure 1-4 Back View

(1) Back bracket of the instrument;

(2) Battery cabin.

1.2. Introduction to Graphical User Interface

This chapter introduces the graphical user interface (GUI) of DTA-SDH/155.

Figure 1-5 Graphical User Interface

(1) Information prompt area: including the error, alarm, insert error, running prompt and electric

⑶

[4]

⑴

⑵



quantity of battery;

(2) Main display area: the display of various functions, setup and test results of the instrument;

(3) Function key area: different function keys in different interfaces to realize the operation of

the instrument;

（4）Language select.

2. Test Configuration

The test configuration interface defines the setup of different test modes, which is the most

basic setup for specific test of instrument, mainly including test mode select, port select, mapping

and test code pattern select. See Figure 2-1 as follows:

Figure 2-1 Test Configuration Interface

Six shortcut keys in the lower part of the interface are defined as follows: “Set”—all parameter setups in the interface are valid;

“Save” —save up the current setup. As in Figure 2-2 Save Interface, a file name can be selcted for saving up the current configuration.

Figure 2-2 Save Interface



“Load”—load a stored configuration file as in Figure 2-3 Configuration File:

Figure 2-3 Configuration File

Click ”Load” to pop up a stored configuration file, select a file name and confirm. In this case,

configuration parameters are the contents of a selected configuration file. Press “Set” to make the

configuration valid.

“Insert”—insert error code, overhead and alarm for a test.

“Start”—press the current configuration to implement a test. When the test starts, the run key

on the upper part of the interface becomes green, and “Start” key changes to “Stop” key. Click the

stop button to suspend the current test. At the same time, the pointer light “Start” on the upper part

of the interface returns to grey;

“Exit”—exit the current interface (test status unchanged), and return to the previous interface.

2.1. Test Mode

As in Figure 2-4, the instrument has nine test modes.

Figure 2-4 Test Mode Interface



2.1.1. SDH Path Mode (Default Mode of the Manufacturer)

For the structure chart, see Figure 2-5 as follows:

Figure 2-5 SDH Path Mode

2.1.2. SDH Demux Mode


Figure 2-6 SDH Path Demux Mode

2.1.3. SDH Mux Mode


Figure 2-7 SDH Mux Mode



2.1.4. SDH Monitor Mode


Figure 2-8 SDH Monitor Mode

2.1.5. SDH Through Mode


Figure 2-9 SDH Through Mode

2.1.6. PDH Path Mode


Figure 2-10 PDH Path Mode

2.1.7. PDH Monitor Mode




Figure 2-11 PDH Monitor Mode

2.1.8. PDH Span Mode


Figure 2-12 PDH Span Mode

2.1.9. PDH Through Mode


Figure 2-13 PDH Through Mode

2.2. Parameter Setup

2.2.1. Physical Interface

The instrument supports electrical port and optical port. In SDH test mode, physical interface

can be selected as optical port-”O” or electrical port- “E” while consistent ports are required for

receiving or transmission i.e. both ”O” or both “E”. In PDH test, only electrical port-“E” is available.

For the physical interface setup, see Figure 2-14 as follows:



Figure 2-14 Physical Interface Setup

2.2.2. Receiving Gain

The instrument supports receiving gain at two levels including 0dB and 18dB. See Figure 2-15

as follows:

Figure 2-15 Receiving Gain Setup

2.2.3. Mapping

The mapping and de-mapping modes: E1 (unframed, CCS, CCS/CRC, CAS & CAS/CRC), E3

(unframed/frame), E4 (unframed/frame), C-12 (KLM optional), C-3 (TUG3 optional), C-4. Receiving

and transmission can be set up separately- “RX≠TX”. Moreover, a coupling mode can be set up-

“RX=TX”. See Figure 2-16 as follows:



Figure 2-16 Mapping Mode Setup

2.2.4. PRBS Code Pattern

For the setup interface of test code pattern, see Figure 2-17 as follows:

Figure 2-17 Test Code Pattern Setup

Options for test code pattern: 2E23, 2E23 (INV), 2E20, 2E20 (INV), 2E15, 2E15 (INV), 2E11,

2E11 (INV), 2E9, 2E9 (INV), 1111 and 0101. The receiving and transmission can be separately set

up. Moreover, the coupling mode can also be selected.

2.2.5. Transmission Clock

For the setup interface of transmission clock, see Figure 2-18 as follows:



Figure 2-18 Clock Setup

2.3. LED Interface

LED interface comprises SDH interface and TCM interface, of which SDH interface includes all

alarms and errors of PDH.

2.3.1. SDH Interface

For the interface, see Figure 2-19 as follows:

Figure 2-19 LED Indicating Diagram

LINE: line-related

LOS: loss of signal on line side

AIS: alarm indicating signal on line side

LOL: loss of locking of line clock



LTC: loss of external clock

RS: related to regenerator section

LOF: loss of frame alignment (6)

OOF: frame alignment (5)

EFAS: frame alignment (1-4)

TIM: trace identifying mark mismatch of regenerator section

B1: error code monitoring of regenerator section, and BIP8 check error

MS: related to mux section

AIS: remote alarm indication of mux section

RDI: remote defect indication of mux section

REI: remote error indication of mux section

B2: error code monitoring of mux section, and BIP-24 check error

AU: related to administration unit pointer

AIS: status indication signal of AU pointer alarm

LOP: loss of AU pointer

+PJE: positive AU pointer adjustment

-PJE: negative AU pointer adjustment

NDF: AU pointer new data symbol

INV: invalid AU pointer

NEW: new AU pointer

PAIS: AU pointer H1, H2 whole 1 alarm indication signal

HP: related to high-order path

UNQ: high-order path unloaded or monitoring unloaded with signal alarm

REI: remote error indication of high-order path

RDI: remote defect indication of high-order path

PLM: payload mismatch alarm of high-order path

TIM: trace identifying mark mismatch of high-order path

B3: error code monitoring of high-order path, and high-order B3 check error

TU: related to bypass pointer

AIS: TU pointer alarm indication signal

LOP: loss of TU pointer

+PJE: positive TU pointer adjustment

-PJE: negative TU pointer adjustment

NDF: new data flag of TU pointer

INV: invalid TU pointer

NEW: new TU pointer

PAIS: TU pointer H1, H2 whole 1 alarm indication signal

LP: related to low-order path

UNQ: low-order path unloaded or monitoring unloaded with signal alarm



REI: remote error indication of low-order path

RDI: remote defect indication of low-order path

PLM: payload mismatch alarm of low-order path

TIM: trace identifying mark mismatch of low-order path

LOM: loss of multiframe

RFI: remote failure indication of low-order path

BIP-2: monitoring of error code of low-order path

Frm: related to frame

LOF: loss of frame alignment

RAI: remote alarm indication

CRCL: CRC loss

EFAS: frame error

ECRC: CRC error

REI: error code of remote block

MAIS: multiframe alarm indication

CASL: multiframe loss

MRAI: multiframe remote alarm indication

PATTERN: related to code pattern

SYNC: PRBS out-of-synchronism

AIS: PRBS whole 1

EBIT: PRBS with error code

SLIP: PRBS slide code

2.3.2. TCM Interface

For TCM interface, see Figure 2-20 as follows:

Figure 2-20 TCM LED Indication Interface

HP: high-order path

UNEQ: signal not equipped with alarm



LTC: TCM frame loss alarm

RDI: TCM remote defect alarm

ODI: TCM output defect alarm

TIM: TCM trace mismatch

REI: TCM remote error alarm

OEI: TCM output error alarm

AIS: TCM alarm indication signal

IEC: TCM input error counting

LP: low-order path

UNEQ: signal not equipped with alarm

LTC: TCM frame loss alarm

RDI: TCM remote defect alarm

ODI: TCM output defect alarm

TIM: TCM trace mismatch

REI: TCM remote error alarm

OEI: TCM output error alarm

AIS: TCM alarm indication signal

IEC: TCM input error counting

3. Error Performance Analyzer

Error performance analyzer is the second option of the main interface as in Figure 3-1:

Figure 3-1 Error Performance Analyzer Interface

The error analyzer includes three parts i.e. tests summary, error test result & error performance analyzer.



3.1. Tests Summary

For tests summary interface, see Figure 3-2 as follows:

Figure 3-2 tests summary

“Start time” refers the time of the system when ”Start” shortcut key is clicked on. “Duration”

refers to the continual time keeping after “Start time”. Click the exit button to stop.

“Send Pat” and “Rev Pat” are the code sample of PRBS in the “Test Configuration“ interface.

“Current status” is error or alarm indication.

3.2. Error Test Result

For error test result interface, see Figure 3-3 as follows:

Figure 3-3 Error Test Result

“Start time” refers the time of system when ”Start” shortcut key is clicked on. “Duration” refers to

the continual time keeping after “Start time”. Click the exit button to stop.

Display items include the error code second and ratio of EBIT and EFAS.

In any interface, click on “Start” shortcut key to start synchronous time keeping and operation.

Click the exit button to stop.



3.3. Error Performance Analyser

3.3.1. SDH Part

Error performance analyzer of SDH part including: G.826, G.828, G.829 and M.2101.

G.826 including: MS, HOPOH, LOPOH; and interface indicators including EB, BBE, BBER, ES,

ESR, SES, SESR, UAS, UASR. See Figure 3-4 as follows:

Figure 3-4 G.826 Analyzer Interface

G.828 including: MS, HOPOH, LOPOH; and interface indicators including EB, BBE, BBER, ES,

ESR, SES, SESR, UAS, UASR, SEP, SEPR. See Figure 3-5 as follows:


G.829 including: RS, MS; and interface indicators including EB, BBE, BBER, ES, ESR, SES,

SESR, UAS, UASR. See Figure 3-6 as follows:




M.2101 including: MS, HOPOH, LOPOH; and interface indicators including EB, BE, BER, ES,

ESR, SES, SESR, UAS, UASR, SEP, SEPR. See Figure 3-7 as follows:

Figure 3-7 M.2101 Analyzer Interface

3.3.2. PDH Part

Error performance analyser of PDH including: G.821, G.826, M.2100.

G.821 interface indicators including: EBIT, EBITR, ES, ESR, SES, SESR, UAS, UASR, See

Figure 3-8 as follows:




G.826 interface indicators including EB, BBE, BBER, ES, ESR, SES, SESR, UAS, UASR as in

Figure 3-9:


M.2100 interface indicators including BE, BER, ES, ESR, SES, SESR, UAS and UASR. See

Figure 3-10 as follows:

Figure 3-10 M.2100 Analyzer Interface



In the performance analyzer interface in above, click on the “Chart” function key to display

various results in a chart as in Figure 3-11:

Figure 3-11 Result Chart

In any interface, click on ”Start” shortcut key to start the synchronous counting and operation.

Click on the exit button to stop time keeping and operation.



4. Event Record

Event record interface including: trace overhead test, regular overhead test, pointer value test,

pointer sequence test, error insert test, insert alarm, pointer adjusting test as in Figure 4-1.

Figure 4-1 Event Record Interface

4.1. Trace Overhead Test

Trace overhead test includes HOPOH (J0, J1) & LOPOH (J0, J2). Each part involves “Transmit

value”, “Expected value” and “Receive value”. The input value or parameter of “Transmit value” and

“Expected value” is set up by the ”Set” shortcut key, of which the result influences display select of

TCM in LED. “Receive value” will not be controlled by a shortcut key and receive in real time. The

initial interface is HOPOH. See Figure 4-2 as follows:

Figure 4-2 Trace Overhead Test

J0 has default value of “111111111111111”. J1 & J2 have default value of “111111111111111”.



4.2. Regular Overhead Test

Including HOPOH and LOPOH. See Figure 4-3 as follows:

Figure 4-3 Regular Overhead Test

The contents include the transmission and receiption of S1, G1, H4, V5, K1, K2, K3, K4 and C2.

The ”Set” shortcut key can set up an input value or parameter of “Transmit value”. “Receive value”

is not controlled by the shortcut key and can receive in real time.

4.3. Pointer Value Test

For pointer value test, see Figure 4-4 as follows:

Figure 4-4 Pointer Value Test

The contents including: “Pointer type”: AU and TU, with a default value of AU.

“NDF”: ON, OFF, with a default value of OFF, where “ON” can be inserted only one time.

Otherwise, the point may be lost. During a test, OFF can be selected.

“Setup SS BITS”: 10.

“Transmit value of pointer“: scope of setup AU 0-782, TU3 0-764, TU12 0-139, with a default

value of 128.



“Receive value of pointer“: receive in real time.

The ”Set” shortcut key can set up the input value or parameter for “Pointer type”, “NDF, “Setup

SS BITS” and “Transmit value of pointer“. “Receive value of pointer“ is not controlled by the shortcut

key and can receive in real time.

4.4. Pointer Sequences Test

For pointer sequences test, see Figure 4-5 as follows:

Figure 4-5 Pointer Sequences Test

The setup contents of “Pointer sequences” include: single-step reversed polarity, adding of one

pair at fixed period, loss of one at fixed eriod, pair of reversed polarity, single step, burst, 87-3, 87-3

plus, 87-3 minus, periodicity, periodicity plus and periodicity minus, with a default value of

“single-step reversed polarity”.

“INIT”: scope of setup 0-1638sec, with a minimum step length of 25ms and default value of 60.

“COOL”: scope of setup 0-1638sec, with a minimum step length of 25ms and default value of

30.

“T1”: scope of setup 0-107374182sec, with a minimum step length of 25ms, time type of

“millisecond, sec, minute, hour ” and default value of 1sec.

“T2”: scope of setup 0-65sec, with a minimum step length of 1ms, time type of “millisecond,

sec ” and default value of 2 millisecond.

“TADD”: scope of setup 0-255, with a default value of1.

“Pointer type”: AU, TU, with a default value of AU.

The “Set” shortcut key can set up all the input values or parameters. Once it is set up, “Insert

mode” changes to the current mode (insert sequence) instead of the original mode with a display on

the upper part of the screen. Then, the ”Insert” shortcut key can implement the insert.



4.5. Error Insert Test

For error insert test, see Figure 4-6 as follows:

Figure 4-6 Error Insert Test

“Start time” refers to the time of system when the “Start” shortcut key is clicked on. “Duration” is

continual time keeping after “Start time”. After the running start, the start button changes to the exit

button. Click on the exit button to step the time keeping and running.

“Insert mode”: rate (default parameter)—1.0E-3, 1.0E-4, 1.0E-5, 1.0E-6, 1.0E-7, 1.0E-8, 1.0E-9,

with a default value of 1.0E-3.

Burst—scope of setup 0-8000, with a default value of 2000.

Repetitive burst—scope of setup 0-8000, with a default value of 2000.

“Insert error”:

Line—ECOD. “Insert mode” can be rate, burst and repetitive burst.

PDH—EFAS, ECRC, REBE. “Insert mode” is continual, with a default value of EFAS.

SDH (default parameter)—B1 (the maximum value of burst or repetitive burst is 8000), B2 (the

maximum value of burst or repetitive burst is 8000), msREI (the maximum value of burst or

repetitive burst is 2000), hpB3 (the maximum value of burst or repetitive burst is 8000), hpREI (the

maximum value of burst or repetitive burst is 8000), lpB3 (the maximum value of burst or repetitive

burst is 8000), lpREI (the maximum value of burst or repetitive burst is 2000), lp3REI (the maximum

value of burst or repetitive burst is 8000), BIP2 (the maximum value of burst or repetitive burst is

2000). “Insert mode” can be rate, burst and repetitive burst, with a default value of B1.

Pattern—EBIT. “Insert mode” can be rate, burst and repetitive burst.


mode” changes to the current mode (insert error code) instead of the original mode with a display

on the upper part of the screen. Then, the ”Insert” shortcut key can implement the insert. Error insert

function is unavailable in PDH test mode.



4.6. Insert Alarm

For insert alarm, see Figure 4-7 as follows:

Figure 4-7 Insert Alarm


continual time keeping after “Start time”. Click on the exit button to stop.

“Insert mode”: continual.

“Insert alarm “:

Line—LOS, AIS.

PDH—LOF, RAI, CRCL, MAIS, CASL, MRAI.

SDH (default parameter)—EFAS, LOF, OOF, msAIS, msRDI, auAIS, hpRDI, hpPLM, hpUNEQ,

tuAIS, tuLOM, lpRFI, lpRDI, lpPLM, lpUNEQ, tuLOP, rsTIM, hpTIM, lpTIM, with a default value of

EFAS.


mode” changes to the current mode (insert alarm) instead of the original mode with a display on the

upper part of the screen. Then, the ”Insert” shortcut key can implement the insert. Insert alarm

function is unavailable in PDH test mode.

4.7. Pointer Adjusting Test

For pointer adjusting test, see Figure 4-8 as follows:



Figure 4-8 Pointer Adjusting Test


continual time keeping after “Start time”. Click on the “Start” shortcut key again to stop.

“Insert mode”: repetitive burst, scope of setup AU 0-2000, TU3 0-2000, TU12 0-500, with a

default value of 500.

“Pointer event “: AU +PJ, AU –PJ, AU INV, TU +PJ, TU –PJ, TU INV.


mode” changes to the current mode (insert pointer) instead of the original mode with a display on

the upper part of the screen. Then, the ”Insert” shortcut key can implement the insert. The default

value is AU+PJ.



5. Function Test

Function test including: APS test, transparency test, TCM test, RTD test and tributary scan test.

See Figure 5 -1 as follows:

Figure 5 -1 Function Test

5.1. APS Test

For APS test, eee Figure 5 -2 as follows:

Figure 5 -2 APS Test

“Trigger”: MS-AIS, AU-AIS, TU-AIS, B1, and B2, with a default value of MS-AIS.

“Switching time “: with a unit of sec, real-time reception and display in the interface.

The “Set” shortcut key can set up all the input parameters of “Trigger”. Test starts immediately

once in the menu, with the display of results in “Switching time“ and “Status“ column. Pay attention

to the interlocking with ”Start” shortcut key.



5.2. Data Path (Transparency) Test

For data path test, see Figure 5 -3 as follows:

Figure 5 -3 Transparency Test

“Trans OH”: D1-D3, D4-D12, E1, E2, F1 and None, with a default value of None.

“Trans Pat”: 2E11, 2E15, 2E20 and 2E23, with a default value of 2E11.

“Rec. OH”: D1-D3, D4-D12, E1, E2, F1 and None, with a default value of None.

“Rec. Pat”: 2E11, 2E15, 2E20, and 2E23, with a default value of 2E11.

In data transparency test and SDH path test, PRBS insert type in interface setup menu includes

an additional “None” option to realize the interlocking of both interfaces. That is to say, the receiving

terminal or/and transmission terminal of both must be None. The last select is applied as the final

parameter of inserting PRBS and can be set up by ”Set” key.

The “Set” shortcut key can set up all the input values or parameters.

5.3. TCM Test

For TCM test interface, see Figure 5 -4 as follows:

Figure 5 -4 TCM Test



“Err Mode”:

Rate (default parameter)—1.0E-3, 1.0E-4, 1.0E-5, 1.0E-6, 1.0E-7, 1.0E-8 and 1.0E-9, with a

default value of 1.0E-3.

Outburst—scope of setup 0-8000, with a default value of 2000.

Repetitive burst—scope of setup 0-8000, with a default value of 2000.

None.

“Err Position”: LP, HP, with a default value of HP.

“Err Event“: tcREI, tcOEI, tcIEC, with a default value oftcREI. The maximum value of burst or

repetitive burst is as follows.

The maximum value of burst or repetitive burst

Type of error code HP VC3 LP VC12 LP

tcREI 8000 8000 2000

tcOEI 8000 8000 2000

tcIEC 8000 8000 2000

Table 5-1 List of the Maximum Values of Burst or Repetititve Burst of Error Code

“Alm Mode”: continual, None (default parameter).

“Alm Position”: LP, HP, with a default value of HP.

“Alm Event“: tcUNQ, tcLTC, tcRDI, tcODI, tcTIM, tcAIS, with a default value of oftcUNQ.

Add None into the error code and alarm mode for inserting TCM respectively, and realize the

interlocking. The last select is applied as the final parameter for inserting TCM and is set up by ”Set”

key.

The “Set” shortcut key can set up all the input values or parameters.

5.4. RTD Test

RTD includes SDH test and PDH test, with test interface as in Figure 5-5:

Figure 5 -5 RTD Test




continual time keeping after “Start time”. Click on the “Exit” shortcut key to stop.

“Current”: indicating the measuring result of current RTD.

“Offset”: scope of setup 0-9999, with a unit of us, and moreover, “Set Offset” can be added with

the value of “Current”.

“Set Offset”: add “Current” to “Offset”.

“State”: measuring, and measured.

“Pat”: indicating current alarm status of SYNC, AIS, EBIT and SLIP.

Test starts once in the menu, with a display of test result in “Current” and “State” column. Pay

attention to the interlocking with the ”Start” shortcut key.

5.5. Tributary Scan Test

For tributary scan test, see Figure 5 -6 as follows:

Figure 5-6 Tributary Scan Test

“Tributary scan”: 1-63 and *(when the receiving part of “Test configuration“ is E1 or VC12), 1-3

(when the receiving part of “Test configuration“ is E3 or C3).

“TUG3”: 1-3 and *, “TUG2”: 1-7 and *, “TU12”: 1-3 and *(when the receiving part of “Test

configuration“ is E1 or VC12).

Click on the “Scan” shortcut key to enter the scan result interface directly. The default value is

to select all.



6. Test Result

The test result includes alarm test result, error code test result, pointer test result, overhead

test result, TCM test result, transparency test result, frequency test result and tributary test result,

with the interface as in Figure 6-1. All test result menus have a save function. Click on the

“Save“ shortcut key to save up the current test results.

Figure 6-1 test result

6.1. Alarm Test Result

For alarm test result interface, see Figure 6-2 as follows:

Figure 6-2 Alarm Test Result

“Alarm type”:

PDH part: including continual seconds of LOS, AIS, LTI, LOF, RAI, CRCL, MAIS, CASL, MRAI,



Pat AIS and Pat LSS. (Only in E1 mode)

SDH part: including LOS, LOF, RS TIM, MS AIS, MS RDI, AU AIS, AU LOP, HP UNEQ, HP RDI,

HP TIM, HP PLM, LTI, Pat AIS, Pat LSS, TU AIS (grey when set up as C4), TU LOP (grey when set

up as C4), LP UNEQ (grey when set up as C4), LP RDI (grey when set up as C4), RFI (grey when

set up as C3 or C4), LP TIM (grey when set up as C4) and LP PLM (grey when set up as C4).

In any interface, click on the “Start” shortcut key to start synchronous counting and operation.

Click on ”Stop” button to stop. Click on the “Chart” shortcut key to generate a dynamic histogram of

alarm test results in this interface directly.

6.2. Error Code Test Result

For error code test result interface, see Figure 6-3 as follows:

Figure 6-3 Error Code Test Result

“Error type”:

PDH part: including error code counting, sec & rate of ECOD, EFAS, ECRC, REBE and EBIT.

(Only in E1 mode)

SDH part: including error code counting, sec & rate of B1, B2, MRAI, HP B3, LP B3 (grey when

set up as C12 or C4), HP REI, LP REI (grey when set up as C4), EBIT and BIP2 (grey when set up

as C3 or C4).


Click on the exit button to stop. Click on the “Chart” shortcut key to generate a dynamic histogram of

error test results in this interface directly.

6.3. Pointer Test Result

For pointer test result interface, see Figure 6-4 as follows:



Figure 6-4 Pointer Test Result

Pointer test result including: pointer value and SS BITS value of AU and TU, and counting and

rate of +AUP JE, -AUP JE, AU NDF, AU INV, +TUP JE, -TUP JE, TU NDF and TU INV.


Click on ”Stop” button to stop. Click on the “Chart” shortcut key to generate a dynamic histogram of

alarm test results in this interface directly.

6.4. Overhead Test Result

For overhead test result interface, see Figure 6-5 as follows:

Figure 6-5 Overhead Test Result

Overhead test result including:

RS: A1, A2, J0, B1, E1, F1, D1, D2, D3

AU: H1, V1, V2, H2, L1, L2, H31, H32, H33

MS: B2, K1, K2, D4, D5, D6, D7, D8, D9, D10, D11, D12, S1, Z1, Z2, M1, E2

TU12: V1, V2, V3, V4

LOPOH: V5, J2, N2, K4

HOPOH: J1, B3, C2, G1, F2, H4, F3, H4, F3, K3, N1

All results aren’t controlled by the shortcut key. Real-time reception and display are available



once in the interface. Click on the ”Stop” button to stop.

6.5. TCM Test Result

For TCM test result interface, see Figure 6-6 as follows:

Figure 6-6 TCM Test Result

The display of the number, error code sec and rate of TC-REI, TC-OEI and IEC of N1 and N2 in

the overhead of high-order & low-order and the duration of TC-UNO, TC-LTC, TC-RDI, TC-TIM,

TC-AIS is available.



6.6. Data Path Test (Transparency) Result

For data path test result interface, see Figure 6-7 as follows:

Figure 6-7 Transparency Test Result

The display of the number, error code sec & rate of EBIT and the alarm time of LSS is available.





6.7. Frequency Test Result

For frequency test result, see Figure 6-8 as follows:

Figure 6-8 Frequency Test Result

“Rev Pat”: PRBS code pattern of the receiving part in setup menu.

“Send Pat”: PRBS code pattern of the transmitting part in setup menu.

“Frequency“: actual frequency for receiving, with a unit of bit/s.

“Offset”: the offset between actual receiving frequency and ideal frequency (155.52Mb/s), with

a unit of ppm.

“Minimum“: the minimum value of the frequency measured in the interface, with a unit of bit/s.

“Maximum“: the maximum value of the frequency measured in the interface, with a unit of bit/s.



6.8. Tributary Test Result

For tributary test result interface, see Figure 6-9 as follows:

Figure 6-9 Tributary Test Result



The display of tributary scan results of VC12 (E1), VC3 (E3) and VC4 (E4) (specified according

to setup mode of the receiving part in setup menu) is available. Real-time reception and display

are available once in the interface. Click on the “Stop” button to stop.



7. System Setup

For the main item of system setup, see Figure 7-1 as follows:

Figure 7-1 System Setup

7.1. File Management

The file management includes configuration file and result file as in Figure 7-2.

Figure 7-2 File Management

7.1.1. Configuration File:

The configuration parameter of nine modes is available. Click on a file, press the configuration

parameter of the file and enter the configuration interface directly as in Figure 7-3:



Figure 7-3 Configuration File

7.1.2. Result File

Ten test results are available as in Figure 7-4:

Figure 7-4 Result Test Interface

7.2. Version Information

View the version information of the current software and hardware as in Figure 7-5 as follows:

Figure 7-5 Version information



7.3. Recover Default

Recover the system to the default setup as in Figure 7-6:

Figure 7-6 Default Recovery

7.4. Time Setup

Set up the time of system as in Figure 7-7:

Figure 7-7 Time Setup

“Date”: YYYY—2000-2030, MM—1-12, DD—1-31.

“Time“: HH—1-23, MM—0-59, SS—0-59.

7.5. Touch Screen Calibration

Click on the below-left corner of screen and then, the screen will prompt to click on the up-right

corner to calibrate the screen as in Figure 7-8 as follows:



Figure 7-8 Touch Screen Calibration Interface

7.6. Other Setup

See Figure 7-9 as follows:

Figure 7-9 Other Setup Interface

“Save Mode”: manual save, save once error interval, and timing save, with a default value

of ”Manual”.

“Save duration”: 5 minute, 15 minute, 30 minute and 1 hour, with a default value of “5minute”.

“KeyPressSound”: On, Off, with a default value of “On”.

“Alarm Sound”: On, Off, with a default value of “On”.

“Contrast”: Always on, Automatic, with a default value of “Auto”.

7.7. Performance Objectives

Set up the indicators of the performance test as in Figure 7-10:



Figure 7-10 Performance Objectives

7.8. USB Connection

USB will connect the instrument with PC via USB port for file loading and software update of

the instrument as in Figure 7-11 as follows:

Figure 7-11 Terminal Wiring Diagram

Contacting Customer Service

Please check our web site (www.shinewaytech.com) for updates to this manual and additional application information. If you need technical or sales support, please contact local Shineway Technologies Customer Service. Shineway Technologies (China), Inc.: Address: Fl.7, Zhongtai Plaza, No.3 Shuangqing Rd, Haidian District, Beijing, China Postal code: 100085 Tel: +86-10-62953388 Fax: +86-10-62958572 Email: [email protected] WEB: www.shinewaytech.com



THANK YOU FOR CHOOSING SHINEWAY TECHNOLOGIES!

dta-sdh/155 operating manual · 2018-03-19 · dta-sdh/155 operating manual shineway technologies,...

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