Paradyne Network Card 3980 A2 GZ40 20 User Manual

TM  
COMSPHERE 3800Plus Modems  
Synchronous Data Compression Feature  
Document Number 3980-A2-GZ40-20  
November 1996  
Overview  
The Paradyne proprietary Synchronous Data Compression (SDC) feature allows an increase of throughput in data  
transmission, and has an error correcting procedure so that transmitted data is less sensitive to channel  
disturbances.  
The ITU-T recommendations V.42bis and V.42 have data compression and error correcting (EC) procedures for  
DCEs connected to asynchronous DTEs. These procedures form the basis of Paradyne’s SDC feature.  
With the SDC feature, two DTEs can exchange data via a synchronous protocol (Figure 1) while the DCE  
provides the new synchronous data compression and error correction functions (Figure 2). The synchronous data  
from the local DTE, after compression, is inserted into DCE frames which are sent to the remote DCE. Inverse  
operations then occur at the remote DCE.  
SDC can be used with V.34 and V.32 family modulations on dial or leased lines, and in a dial backup or standby  
mode.  
SDC is available as an installable option beginning with firmware Release 3.0.  
SYNCHRONOUS PROTOCOL  
19.2 Kb/s  
9.6 Kb/s  
19.2 Kb/s  
SYNCHRONOUS  
DTE  
SYNCHRONOUS  
DTE  
DCE  
DCE  
495-14784  
Figure 1. Sample DTE Exchange of Data via Synchronous Protocol and SDC  
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10. Perform a power reset:  
For a standalone modem, turn the Power switch to the Off position, then to the ON position, or  
For a carrier-mounted modem, release the lock, slide the modem part of the way out of the carrier, then  
replace it and lock it in place.  
11. Set the SDC configuration options suitable for your environment. See Tables 1 and 2.  
Installing the SDC Feature Using AT Commands  
To install SDC using AT commands, use this procedure.  
1. Attach a DTE to the modem.  
2. Load the Async Dial factory template:  
From the DCP, select Async Dial from the Factory group of the Configure branch, or  
If AT commands are enabled, enter the AT&F0 command.  
3. Install the SDC feature. Enter the command: AT&&I12=011993  
The modem responds OK.  
4. Perform a power reset. Enter the command: ATZ9  
5. Check the installed features. Enter the command: AT&&I0  
The modem responds with a list of features installed in your modem, including SDC.  
6. Set the SDC configuration options suitable for your environment. See Tables 3 and 4.  
Menu Status and Result Codes  
When SDC is active and the modem is online, the top line of the DCP display shows Online:mrV42t,  
Leased:mrV42t, Backup:mrV42t, or Stndby:mrV42t, where mr is the modem rate. For example,  
Online:33.6V42t is displayed on the DCP of a modem using SDC and connected to a dial line at 33,600 bits per  
second (bps).  
When extended result codes are set to contain the data compression protocol, and SDC is active, connect  
messages include the characters V42t. For example, when a modem with SDC active connects to a dial line at  
33,600 bps, the result code CONNECT 33600/V42t/RX=33600/TX=33600 is sent to the DTE.  
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SDC User Interface  
When SDC is enabled, the following configuration options are available to set up the SDC feature. Some of the  
configuration options are not displayed unless SDC is enabled.  
V.42/MNP/Buffer (see Table 1)  
Sync Comp Mode  
SDC Negotiation  
SDC Idle Fill  
SDC Bit Encoding  
Sync DTE CRC  
SDC Delay Min  
Sync Flow Control  
TX Buff Disc Delay  
RX Buff Disc Delay  
Max Frame Size  
Cellular Enhance  
DTE Interface (see Table 2)  
Sync DTE Rate  
Tx Clock Source  
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Table 1  
(1 of 3)  
V.42/MNP/Buffer Configuration Options for SDC  
Sync Comp Mode: DirectMode  
Nxt DirectMode HDLC/SDLC  
This configuration option only appears if Async/Sync Mode is configured for Sync.  
Synchronous Compression Mode. Enables and disables synchronous data compression.  
DirectMode – Disables the Synchronous Data Compression mode.  
HDLC/SDLC – Enables the Synchronous Data Compression mode  
The AT command for Sync Comp Mode is #SCn. See Table 3, page 9.  
SDC Negotiation: LAPM_Buffer  
Nxt LAPM_Buffer LAPM_Discon  
This configuration option only appears when the Async/Sync Mode configuration option is set to Sync and Sync  
Comp Mode configuration option is not set to DirectMode.  
Synchronous Data Compression Negotiation. Determines the type of negotiation used when the modem attempts to  
connect using SDC. See Table 5, page 15.  
Link Access Procedure for Modems or Buffer – The modem attempts to establish an SDC connection. If the remote  
modem has SDC capability, then the connection is established with SDC active. If the remote synchronous modem does  
not have SDC capability, then the local connection is made in Buffer mode.  
Link Access Procedure for Modems or Disconnect – The modem attempts to establish an SDC connection. If the  
remote modem has SDC capability, then the connection is established with SDC active. If the remote modem does not  
have SDC capability, then no connection occurs and the modem generates a disconnect.  
The AT command for SDC Negotiation is S28=n. See Table 4, page 10.  
SDC Idle Fill: Flag_Fill  
Nxt Flag_Fill Mark_Fill  
This configuration option only appears when the Async/Sync Mode configuration option is set to Sync and Sync  
Comp Mode configuration option is not set to DirectMode.  
Synchronous Data Compression Idle Fill. Determines whether the modem uses an HDLC flag or mark to fill the time  
between DTE frame transfers.  
Flag_Fill – Causes the modem to fill the time between DTE frame transfers with HDLC flags.  
Mark_Fill – Causes the modem to fill the time between DTE frame transfers with marks.  
The AT command for SDC Idle Fill is S29=n. See Table 4, page 10.  
SDC BitEncoding: NRZ  
Nxt NRZ NRZI  
This configuration option only appears when the Async/Sync Mode configuration option is set to Sync and Sync  
Comp Mode configuration option is not set to DirectMode.  
Synchronous Data Compression Bit Encoding. Determines the type of bit encoding scheme (NRZ or NRZI) the modem  
uses when transmitting synchronous DTE data.  
NRZ – Causes the modem to use the standard Non Return to Zero bit encoding scheme.  
NRZI – Causes the modem to use the Non Return to Zero Inverted bit encoding scheme.  
The AT command for SDC Bit Encoding is S31=n. See Table 4, page 11.  
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Table 1  
(2 of 3)  
V.42/MNP/Buffer Configuration Options for SDC  
SyncDTE CRC: Ignore  
Nxt Ignore CRC16  
This configuration option only appears when the Async/Sync Mode configuration option is set to Sync and Sync  
Comp Mode configuration option is not set to DirectMode.  
Synchronous DTE CRC. Determines whether the CRC of the DTE frame is transmitted from modem to modem.  
Ignore – No assumption is made about the CRC type. The CRC is transmitted along with the other data in the frame.  
16  
CRC16 – The CRC is known to be the 16-bit CRC for HDLC frames defined by ITU-T (generator polynomial x  
x
+
12  
5
+ x + 1). It is removed from the DTE frame by the sending modem and added to the DTE frame by the receiving  
modem.  
The AT command for SyncDTE CRC is S32=n. See Table 4, page 11.  
SDC Delay Min: Off  
Nxt Off Rx_Clock  
This configuration option only appears when the Async/Sync Mode configuration option is set to Sync and Sync  
Comp Mode configuration option is not set to DirectMode.  
Synchronous Data Compression Delay Minimization. Allows the modem to transmit a DTE frame to its DTE in a  
discontinuous way to minimize the delay introduced by SDC processing.  
Off – The modem does not begin transmitting a frame to its DTE until the entire frame has been received.  
Rx_Clock – The modem begins to transmit data from a DTE frame to its DTE even if the end of the DTE frame has not  
yet been received by the modem. The receive clock (circuit 115) is clamped when the beginning of a DTE frame has been  
transmitted to the DTE and no other data from this DTE frame has been received by the modem. As soon as data from  
the current DTE frame can be transmitted to the DTE, the receive clock is released. The Rx_Clock option appears only if  
the Tx Clock Source configuration option is set to Internal.  
The AT command for SDC Delay Min is #DMn. See Table 3, page 9.  
Sync Flow Cntrl: None  
Nxt None Tx_Clock CTS_SyncDTE  
This configuration option only appears when the Async/Sync Mode configuration option is set to Sync and Sync  
Comp Mode configuration option is not set to DirectMode.  
Synchronous Flow Control. Controls the type of synchronous data flow control while using data compression.  
None – Modem does not control the flow from the synchronous DTE.  
Tx_Clock – The transmit clock (circuit 114) clamps when the modem is unable to accept supplementary data from the  
DTE. Tx_Clock appears only if the Tx Clock Source configuration option is set to Internal.  
CTS_SyncDTE – CTS signal circuit (106) is set to OFF when the modem is unable to accept supplementary data from  
the DTE.  
The AT command for Sync Flow Cntrl is #Qn. See Table 3, page 9.  
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Table 1  
(3 of 3)  
V.42/MNP/Buffer Configuration Options for SDC  
TXBuffDiscDelay: 10sec  
Nxt 10sec Disable 60sec  
This configuration option only appears when Async/Sync Mode is configured for Async, and Error Control Mode  
is not configured for DirectMode, or when Async/Sync Mode is configured for Sync and Sync Comp Mode is not  
configured for DirectMode.  
Transmit Buffer Disconnect Delay. Determines how long the modem continues to transmit data stored in its Transmit  
buffer when the modem is commanded to disconnect by a locally attached DTE.  
Disable – Modem disconnects immediately without attempting to send data stored in its buffer.  
10, 60 sec – Maximum amount of time the modem tries to empty its buffer before disconnecting. In both cases (10 sec  
and 60 sec), the modem disconnects much sooner if it can empty its buffer.  
The AT command for TXBuffDiscDelay is S49=n.  
RXBuffDiscDelay: 10sec  
Nxt 10sec Disable 60sec  
This configuration option only appears when Async/Sync Mode is configured for Async, and Error Control Mode  
is not configured for DirectMode, or when Async/Sync Mode is configured for Sync and Sync Comp Mode is not  
configured for DirectMode.  
Receive Buffer Disconnect Delay. Determines how long the modem continues to send to the DTE data stored in its  
Receive buffer when the modem is commanded to disconnect by a locally attached DTE, or detects a line disconnect.  
Disable – Modem disconnects immediately without attempting to send data stored in its buffer.  
10, 60 sec – Maximum amount of time the modem tries to empty its buffer before disconnecting. In both cases (10 sec  
and 60 sec), the modem disconnects much sooner if it can empty its buffer.  
The AT command for RXBuffDiscDelay is S39=n.  
Max Frame Size: 256  
Nxt 256 192 128 64 32 16  
This configuration option only appears when Async/Sync Mode is configured for Async, and Error Control Mode  
is not configured for BufferMode or DirectMode, or when Async/Sync Mode is configured for Sync and Sync  
Comp Mode is not configured for DirectMode.  
Maximum Frame Size. Sets the maximum frame size for V.42 and MNP. For MNP operation, 64 is the minimum value.  
Any value less than that will automatically default to 64. For cellular applications, at least one of the sides should be set to  
a low value. A setting of 32 is recommended. Only one modem needs this setting; both modems will automatically default  
to the greatest common value.  
The AT Command for Max Frame Size is \An.  
CellularEnhance: Disable  
Nxt Disable Enable  
This configuration option only appears when Async/Sync Mode is configured for Async, and Error Control Mode  
is configured for V42/MNPorBfr, V42MNPorDsc, LAPM_or_Disc, or LAPM_or Bfr, or when Async/Sync Mode is  
configured for Sync and Sync Comp Mode is not configured for DirectMode.  
Cellular Enhancement. When enabled, the modem uses non-standard techniques to enhance V.42 operation for cellular  
applications. It is still compatible, however, with modems which do not have the cellular enhancement implemented or  
enabled.  
The AT command for CellularEnhance is S91=n.  
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Table 2  
DTE Interface Configuration Options for SDC  
Sync DTE Rate: 128000  
Nxt 128000 115200 112000 96000 76800 72000 64000 57600 56000 48000 38400 28800 19200 14400  
9600 4800 2400 1200  
This configuration option does not appear when:  
Async/Sync Mode configuration option is set to Async.  
Sync Comp Mode configuration option is set to DirectMode.  
Tx Clock Source configuration option is set to External.  
The SDC feature is disabled.  
Synchronous DTE Data Rate. Identifies the synchronous DTE’s operating rate to the modem. Data rates from  
128,000 bps to 1200 bps are supported.  
NOTE: A cable less than fifty feet in length is required for rates over 19,200 bps. Data synchronization at rates over  
57,600 bps is sensitive to cable length and capacitance, and the DTE’s drivers and receivers. External transmit  
clocking may be required.  
The AT command for Sync DTE Rate is S30=n. See Table 4, page 10.  
Tx Clock Source: Internal  
Nxt Internal External RXC_Loop  
This configuration option only appears when Async/Sync Mode is configured for Sync.  
Transmit Clock Source. Determines the source of timing for synchronous data transmitted from the DTE.  
Internal – The transmit data’s clock source is derived from the modem’s internal clock. This clock is available as an  
output on Pin 15 (TXC) of the EIA-232-D interface.  
External – The transmit data’s clock source is provided by the DTE on Pin 24 (XTXC) on the EIA-232-D interface.  
Receive Clock Loop – The modem’s transmit clock is derived from its received analog signal. The derived clock is  
available as an output on Pin 15 (TXC) of the EIA-232-D interface.  
NOTE: RXC_Loop does not appear if SDC is enabled.  
NOTE: TMp tributaries are forced to RXC_Loop.  
The AT command for Tx Clock Source is &Xn.  
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Table 3  
AT Commands for SDC  
DCP LCD  
Command  
Sequence  
AT  
Command  
Description  
#DMn  
SDC Delay Minimization.  
Configure\Edit\  
V42/MNP/Buffer  
Minimizes the delay introduced by SDC by allowing the modem to transmit a  
DTE frame to its DTE in a discontinuous way.  
#DM0  
No delay minimization. The modem does not begin transmitting a  
frame to its DTE until the entire frame has been received.  
Delay minimization. The modem begins to transmit data from a  
DTE frame to its DTE even if the end of the DTE frame has not yet  
been received by the modem.  
#DM1  
The factory setting is No Delay Minimization.  
#Qn  
Sync Flow Ctrl. Synchronous Flow Control of DTE.  
Configure\Edit\  
V42/MNP/Buffer  
Controls the type of synchronous data flow control while using data  
compression.  
#Q0  
#Q1  
#Q2  
No flow control.  
Flow control using transmit clock (circuit 114).  
Flow control using CTS (circuit 106).  
The factory setting is No Flow Control.  
#SCn  
Sync Comp Mode. Synchronous Compression Mode.  
Enables and disables synchronous data compression.  
Configure\Edit\  
V42/MNP/Buffer  
#SC0  
#SC1  
Disable Synchronous Data Compression mode.  
Enable Synchronous Data Compression mode.  
The factory setting is Disable.  
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Table 4  
(1 of 2)  
S-Registers for SDC  
DCP LCD  
Command  
Sequence  
S-Register  
Description  
S28  
SDC Negotiation.  
Configure\Edit\  
V42/MNP/Buffer  
Controls negotiation between two modems attempting to connect using SDC.  
Register has the following values:  
0 = LAPM_Buffer  
1 = LAPM_Discon  
The factory setting is LAPM_Buffer.  
SDC Idle Fill.  
S29  
Configure\Edit\  
V42/MNP/Buffer  
Determines whether the modem uses an HDLC flag or mark to fill the time  
between DTE frame transfers.  
Register has the following values:  
0 = Flag_Fill  
1 = Mark_Fill  
The factory setting is Flag_Fill.  
S30  
Sync DTE Rate. Synchronous DTE Rate.  
Configure\Edit\  
DTE Interface  
Identifies the synchronous DTE’s operating rate to the modem.  
Register has the following values:  
0 = 128,000 bps  
1 = 115,200 bps  
2 = 112,000 bps  
3 = 96,000 bps  
4 = 76,800 bps  
5 = 72,000 bps  
6 = 64,000 bps  
7 = 57,600 bps  
8 = 56,000 bps  
9 = 48,000 bps  
10 = 38,400 bps  
11 = 28,800 bps  
12 = 19,200 bps  
13 = 14,400 bps  
14 = 9600 bps  
15 = 4800 bps  
16 = 2400 bps  
17 = 1200 bps  
The factory setting is 128,000 bps.  
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Table 4  
(2 of 2)  
S-Registers for SDC  
DCP LCD  
Command  
Sequence  
S-Register  
Description  
S31  
SDC Bit Encoding.  
Configure\Edit\  
V42/MNP/Buffer  
Determines the type of bit encoding used when transmitting synchronous DTE  
data.  
Register has the following values:  
0 = NRZ  
1 = NRZI  
The factory setting is NRZ.  
SyncDTE CRC.  
S32  
Configure\Edit\  
V42/MNP/Buffer  
Determines whether the CRC of the DTE frame is transmitted from modem to  
modem.  
Register has the following values:  
0 = Ignore  
1 = CRC16  
The factory setting is Ignore.  
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Synchronous Data Format  
The SDC feature supports the High-level Data Link Control (HDLC) and Synchronous Data Link Control  
(SDLC) type protocols for synchronous DTE data. An HDLC frame is composed of an information field  
containing the data to transmit, plus an overhead (address, control, and FCS fields) used by the DTE protocol.  
Flags opening and closing the HDLC frame serve as frame delimiters (Figure 3).  
FLAG  
ADDRESS  
CONTROL  
INFORMATION  
FCS  
FLAG  
495-14783  
Figure 3. Synchronous Data Format  
A 3800Plus modem with the SDC feature supports DTE frame sizes up to 4300 bytes. This conforms to the X.25  
recommendation which defines a maximum size of data packets as equal to 4096 bytes.  
If the modem has the SDC Delay Min configuration option set to Rx_Clock, there is no limitation on the DTE  
frame size for the DTE frames transmitted from the remote modem to this local modem, since the whole frame  
need not be buffered.  
The SyncDTE CRC configuration option determines whether the CRC of the DTE frame (the FCS field) is  
transmitted. If the CRC type is known to be the 16-bit CRC for HDLC frames as defined by ITU-T (generator  
16  
12  
5
polynomial x + x + x + 1), the CRC can be removed by the local modem and added to the DTE frame by the  
remote modem.  
SDC Algorithm  
The compression algorithm is based on V.42bis British Telecom Lempel ZIV (BLTZ).  
DTE and DCE Frames  
Data exchanged between the local and remote DCEs is according to the LAPM protocol. The structure of a  
LAPM frame (DCE frame) is identical to the HDLC frame. The data from the DTE is compressed into the  
information field of the DCE frame. After compression, one DTE frame is segmented into one or several DCE  
frames.  
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Data Synchronization  
Data exchanged between the synchronous DTE and the modem is synchronized by two clock signals. Data  
coming from the DTE is synchronized by the transmit clock and data received by the DTE is synchronized by the  
receive clock. The transmit clock is provided by the modem on circuit 114 or by the synchronous DTE on  
circuit 113. The receive clock is provided by the modem on circuit 115.  
When the transmit clock is provided by the modem, the transmit and receive clocks are locked on the same clock  
source internal to the modem. In this configuration, the user can select rates on the DTE-DCE line (or clock  
frequencies) in the range from 1.2 kHz to 128 kHz.  
When the transmit clock is provided by the DTE, the receive clock is set by the modem equal to the DTE clock  
(Figure 4). When SDC is in use, the Tx Clock Source configuration option cannot be set to Receiver Clock Loop.  
NOTE  
When faster speeds are used (above 57.6 kHz), and the transmit clock is  
provided by the modem, data transmission can be sensitive to DTE cable  
length and capacitance, as well as the DTE’s drivers and receivers. Should  
you encounter bit errors related to the above conditions, you may want to  
change the Tx Clock Source configuration option setting to External  
(provided the DTE can support the required transmit clock signal) or  
change the length of the DTE cable.  
DCE  
XTCLK (113)  
TXC (114)  
DTE  
RXC (115)  
CLOCK  
SOURCE  
495-14782  
Figure 4. Clocks at the DTE–DCE Interface  
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Flow Control Method  
The data transmitted from the DTE is sent to the DCE at a rate determined by the transmit clock frequency. When  
SDC is active, this data is then compressed in the DCE and sent to the remote DCE at the line rate less than the  
rate between the DTE and DCE (usually twice, three, or four times less). If the data sent by the DTE is not  
compressible, or bad line conditions cause retransmissions between the two DCEs, then the transmitting DCE  
must indicate to the transmitting DTE its temporary inability to accept more data; this is flow control. Flow  
control is also required in Buffer mode since the DTE rate and line rate can be different. Three methods are used  
to control the DTE flow:  
Hardware signal CTS (circuit 106).  
Transmit clock (circuit 114). If the transmit clock is clamped, then the DTE stops sending data. This  
method only works when the transmit clock is provided by the modem.  
Natural flow control. Some DTEs can only send a limited number of information frames without any  
acknowledgment from the remote DTE. This number is the acknowledgment window size. If the DCE  
buffers this number of DTE frames, it will not receive another DTE frame. This is equivalent to the  
SyncFlowControl configuration option being set to None.  
SDC Negotiation  
The use of SDC and the values of the associated parameters are negotiated at link establishment via a protocol.  
The three associated parameters have the same meaning as those used for asynchronous data compression:  
Dictionary size parameter  
Maximum string length parameter  
Data compression request parameter  
The SDC Negotiation configuration option determines how two modems connect when one or both modems have  
SDC enabled. Two settings are available in the SDC Negotiation configuration option: LAPM_Buffer and  
LAPM_Discon.  
Table 5 shows the six possible SDC Negotiation configuration scenarios.  
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Table 5  
SDC Negotiation Configuration Scenarios  
Originating Modem  
Answering Modem  
Negotiation Results  
SDC enabled with LAPM_Buffer  
negotiation.  
SDC enabled.  
SDC connection.  
SDC enabled with LAPM_Discon  
negotiation.  
SDC enabled.  
SDC disabled.  
SDC disabled.  
SDC connection.  
SDC enabled with LAPM_Buffer  
negotiation.  
Buffer mode connection.*  
Disconnect.**  
SDC enabled with LAPM_Discon  
negotiation.  
SDC disabled.  
SDC disabled.  
SDC enabled with LAPM_Buffer negotiation. Buffer mode connection.*  
SDC enabled with LAPM_Discon negotiation. Disconnect.***  
* If during the negotiation phase, the modem with SDC enabled receives data from the remote modem indicating that it  
has SDC disabled, the link will not be established between the two modems. For example, the link will not be  
established if the remote modem is configured for Async mode with an EC mode of V42/MNPorBfr, V42/MNPorDsc,  
LAPM_Buffer, or LAPM_Discon.  
** On a leased line, the originating modem sends an endless EC negotiation sequence with the SDC request parameter.  
Data cannot be successfully transmitted.  
*** On a leased line, the answering modem waits indefinitely for an EC negotiation sequence with an SDC request  
parameter. Data cannot be successfully transmitted.  
Monitoring SDC Performance  
If SDC is enabled, six performance measurements related to SDC can be displayed on the DCP. These  
measurements are available in the SDC submenu of the Status branch and are divided into two groups: TX  
(transmit) measurements and RX (receive) measurements.  
“Status”  
Test  
Configure  
Control  
Remote  
Security  
Call_Setup  
Status  
VF  
Identity  
DTE  
SDC  
Options Record  
496-14951  
TX  
RX  
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Both groups have DTE Rate, Compression Ratio, and Line Efficiency measurements. Each measurement is an  
average of the last ten seconds’ data, and is updated every second. See Table 6.  
Table 6  
SDC Performance Measurements  
Group  
DTE Rate  
Compression Ratio  
Line Efficiency  
TX  
RX  
The number of bits per second  
received from the DTE. This  
number takes into account only  
the data between the opening and calculation does not include the  
closing flags of the HDLC frames. overhead of the LAPM frame or  
Flags and DTE interframe time fill the DTE flags and DTE  
The ratio between the number of The ratio between the number of  
bits in the input and output of the bits per second sent on the line,  
compression algorithm. The  
and the line rate. The calculation  
does not include the DCE  
interframe time fill.  
are ignored.  
interframe time fill.  
The number of bits per second  
sent to the DTE. This number  
takes into account only the data  
The ratio between the number of The ratio between the number of  
bits in the output and input of the bits per second received from  
decompression algorithm. The  
the line, and the line rate. The  
calculation does not include the  
DCE interframe time fill.  
between the opening and closing calculation does not include the  
flags of the HDLC frames. Flags  
and DTE interframe time fill are  
ignored.  
overhead of the LAPM frame or  
the DTE flags and DTE  
interframe time fill.  
Tuning SDC Efficiency  
SDC efficiency is dependent on the configuration parameters of the DTE and the modem.  
DTE Configuration  
The way DTE parameters are changed, and whether they can be changed, depends on your DTE. See the  
documentation that came with your DTE.  
DTE rate configuration parameter. The nominal DTE rate (the Tx/Rx clock’s frequency at the DTE/DCE  
interface) can be a bottleneck. Increase the nominal DTE rate:  
If the DTE rate measurement reported by your modem is close to the nominal DTE rate.  
If the Line Efficiency measurement reported by your modem is substantially less than 100 percent.  
If the ratio between the nominal DTE rate and the line rate is less than the Compression Ratio.  
DTE acknowledgment window size configuration parameter. This is the number of information frames the  
DTE will send without awaiting positive acknowledgment. Increase the DTE acknowledgment window size if  
your modem reports a low DTE rate and a comparatively high Compression Ratio (and therefore a Line  
Efficiency measurement substantially less than 100 percent). Set it to the maximum possible value.  
DTE frame size configuration parameter. If SDC modems are used between synchronous DTEs, then the DCE  
frame size (and not the DTE frame size) must take into account the line error rate. Set the DTE frame size to as  
large a value as your DTE and your DTE application can handle. This reduces the significance of DTE frame  
overhead, and reduces the delay (expressed in number of DTE frames) for positive acknowledgment.  
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Modem Configuration  
There are also configuration options in the V42/MNP/Buffer branch of the 3800Plus modem which affect SDC  
efficiency.  
(LAPM) Max Frame Size. Except in environments where line impairments are known to be unusually high, set  
this to the maximum (256).  
Sync DTE CRC. If the CRC type of the DTE frame is the 16-bit CRC for HDLC frames as defined by ITU-T, set  
this to CRC16.  
SDC Delay Min. If clamping of the receive clock (circuit 115) is accepted by your DTE, then set this to  
Rx_Clock.  
Sync Flow Cntrl. The Tx_Clock selection is suitable for most synchronous DTEs. If your DTE interprets  
transmit clock clamping or a drop in CTS as a problem (resulting in an aborted frame), set Sync Flow Cntl to  
None. Selecting None should not be a problem if the entire acknowledgment window of DTE frames does not  
exceed 5 kilobytes, so that it can be buffered by the modem.  
Software License Agreement  
THIS AGREEMENT CONTAINS THE PARADYNE CORPORATION LIMITED USE SOFTWARE LICENSE  
TERMS FOR THE SYNCHRONOUS DATA COMPRESSION FEATURE FOR COMSPHERE 3800PLUS  
MODEMS (HEREINAFTER THE “SOFTWARE”).  
YOU SHOULD READ THE TERMS AND CONDITIONS OF THIS AGREEMENT BEFORE YOU USE THE  
SOFTWARE. ONCE YOU HAVE READ THIS LICENSE AGREEMENT AND AGREE TO ITS TERMS, YOU  
MAY USE THE SOFTWARE. BY USING THE SOFTWARE, YOU SHOW YOUR ACCEPTANCE OF THE  
TERMS OF THIS LICENSE AGREEMENT.  
The terms and conditions of this Agreement will apply to the Software supplied herewith and derivatives obtained  
therefrom, including any copy. If you have executed a separate written agreement covering the Software supplied  
herewith, such agreement will govern.  
1. TITLE AND LICENSE GRANT  
a. The Software is copyrighted and/or contains proprietary information protected by law. All Software,  
and all copies thereof, are and will remain the sole property of Paradyne or its suppliers. Paradyne  
hereby grants you a personal, non-transferable and non-exclusive right to use the Software on a single  
modem. Any other use of the Software shall automatically terminate this license.  
b. Use of the Software anywhere except in the United States may, in addition to the terms and conditions  
of this License Agreement, be subject to the terms and conditions of a separate written agreement  
signed by the user.  
c. You agree to use your best efforts to see that any user of the Software complies with the terms and  
conditions of this License Agreement, and refrains from taking any steps, such as reverse assembly or  
reverse compilation, to derive a source code equivalent of the Software.  
d. Software and documentation copyright e 1996 Paradyne.  
November 1996  
17  
3980-A2-GZ40-20  
 
2. SOFTWARE USE  
a. The Software  
(1) shall be disabled or deleted when no longer used in accordance with this License Agreement, or  
when the right to use the software is terminated; and  
(2) shall not be removed from a country in which use is licensed.  
3. TERM  
This license is effective until terminated. You may terminate it at any time by destroying the  
documentation and requesting that Paradyne disable or delete the Software on your modem. It will also  
terminate automatically if you fail to comply with any of the terms and conditions of this Agreement.  
4. LIMITATION OF LIABILITIES  
a. Paradyne has used reasonable efforts to minimize defects and errors in the Software. However, you  
assume the risk of any and all damage or loss from use or inability to use the software.  
b. Unless a separate agreement for software support is entered into between you and Paradyne, Paradyne  
bears no responsibility for supplying assistance for fixing errors or for communicating known errors  
to you pertaining to the Software.  
5. CHARGES AND USE  
YOU ACKNOWLEDGE THAT YOU HAVE READ THIS AGREEMENT AND UNDERSTAND IT,  
AND THAT BY USING THE SOFTWARE YOU AGREE TO BE BOUND BY THE TERMS AND  
CONDITIONS HEREIN. YOU FURTHER AGREE THAT EXCEPT FOR ANY SEPARATE WRITTEN  
AGREEMENTS BETWEEN PARADYNE AND YOU, THIS AGREEMENT IS THE COMPLETE AND  
EXCLUSIVE STATEMENT OF THE RIGHTS AND LIABILITIES OF THE PARTIES. THIS  
AGREEMENT SUPERSEDES ALL PRIOR ORAL AGREEMENTS, PROPOSALS OR  
UNDERSTANDINGS, AND ANY OTHER COMMUNICATIONS BETWEEN US RELATING TO THE  
SUBJECT MATTER OF THIS AGREEMENT.  
18  
November 1996  
3980-A2-GZ40-20  
 

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