Patton electronic 2720 user manual Line Coding B8ZS default Options AMI, B8ZS, B7ZS

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ESF: This stands for Extended Superframe Format, a line format developed by AT&T. AT&T Technical Reference 54016 (TR 54016) defines the ESF, a format which is commonly used to allow monitoring of the network interface performance over the Facility Data Link (FDL). AT&T TR 62411 says, “the Extended Superframe Format “extends” the DS1 superframe structure from 12 to 24 frames…for a total of 4632 bits. It redefines the 8 kb/s channel previously used exclusively for terminal and robbed bit signaling synchronization.” The ESF provides a 4 kb/s data link, called the FDL, which allows for in-service monitoring and fast troubleshooting. Certain net- work services require the ESF.

UNFRAMED:This is a special mode that allows you to achieve the maximum possible data rate of 1.544 Mb/s (million bits per second) by using the framing bits for data transmission. There is no signaling or FDL. This is commonly used for campus connections, and by the Federal government and the military. This format is not to be used when connecting to a public car- rier’s network without its permission. This provides one chan- nel at a rate of 1.544 Mb/s. In addition, this format can be used with external clocking.

bLine Coding: B8ZS (default)

Options: AMI, B8ZS, B7ZS.

AMI: Alternate Mark Inversion defines a pulse as a “mark”, a binary one, as opposed to a zero. In a T1 (DS1) network con- nection, signals are transmitted as a sequence of ones and zeros. Ones are sent as pulses, and zeros are sent as spaces, i.e., no pulse. Every other pulse is inverted from the previous pulse in polarity, so that the signal can be effectively transmitted. This means, however, that a long sequence of zeros in the data stream will cause problems, since the CSU/DSU receiving the signal relies on the signal to recover the 1.544 Mb/s clock. To get around this problem, one method is to limit the data rate per channel (known as a DS0, because it is a 64 kb/s portion of the DS1 frame or super- frame) to 56 kb/s and forcing a pulse in the last data bit to ensure a minimum pulse density in the signal. If you must use AMI with a DS0 data rate of 64 kb/s, you should ensure that the data terminal equipment connected to the unit provides a minimally acceptable pulse density. For this reason, there are advantages to using B8ZS instead.

B8ZS: Bipolar violations occur when consecutive pulses are of the same polarity. In B8ZS, or Bipolar Eight Zero Substitution, bipolar violations are introduced deliberately to indicate that eight zeros have been transmitted. This special encoding is recognized by the receiver and decoded correctly. See AT&T TR62411 Section 4.2.2 for a detailed description of B8ZS. This enables information to be sent over a T1 connection with- out any constraints on the data’s pulse density. This is the most acceptable way to accomplish 64 kb/s on each DS0 channel.

B7ZS: This stands for Bipolar Seven Zero Substitution. Instead of introducing bipolar violations, this method substitutes a one for a zero in bit 7 (out of 8) of a DS0 channel when the data in that channel are all zeros. This is a special form of AMI and is compatible only with special equipment. For most applications, AMI or B8ZS will suffice.

cDS0 Line Rate: 64kbps (default)

Options: 64kbps, 56kbps

64kbps: Also known as Clear Channel, this takes full advantage of the available bandwidth in a DS0 channel. Implementing it usually requires B8ZS line coding. In certain cases, special equipment may implement Clear Channel using AMI or B7ZS. Consult the equipment manual for compatibility. Your carrier will advise you on whether to use 64 or 56 kb/s. Campus applications may not have such restrictions, enabling you to use 64kbps. In Unframed format, the 24 DS0s and the framing bits are combined to provide 1.544Mb/s for your use.

56kbps: This uses only the first seven bits of the DS0, limiting the data rate per DS0 channel to 56 kb/s. Your carrier will advise you on whether to use 64 or 56 kb/s. This is not available when using the Unframed format.

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Contents User Manual Radio and TV Interference Table of ContentsWarranty Information Warranty StatementFCC Part 68 Compliance Statement Industry Canada NoticeFCC Information General Information Service InformationFeatures CE NoticeApplications S2 Summary Table Switch S1-2 Reserved Switch S2-6 and S2-7 Clock ModeSwitch S2-8 Reserved Switch S1 Switch S1-1 RDL TypeVT100 Switches S1-4 and S1-5 Line Build OutSwitch S1-6 Through S1-8 Reserved Software ConfigurationHelpful Hints Introduction to Main MenuLine Format ESF default Options ESF, D4, Unframed System ConfigurationDS0 Line Rate 64kbps default Options 64kbps, 56kbps Line Coding B8ZS default Options AMI, B8ZS, B7ZSOptions Network, Internal, External ESF Carrier Loops Enabled default Options Enabled, DisabledDefault Config Source Switch default Option EEPROM, Switch 54 Loops RDL Only Enabled default Options Enabled, DisabledSpacebar System DiagnosticsLocal Loop Idle default Remote Loop Idle defaultNI Status Test Pattern Idle default Options Idle or SendingError Insertion Off default Options On, Off Selected PatternRx PRM Error CountersCurrent DIP Switch Settings Valid Interval Count & Current Interval TimeUnit Information PasswordLoop Timeout Set to Default ConfigurationT1/FT1 Interface Connection Connecting the 10Base-T Ethernet Port to a PC DTEConnecting the 10Base-T Ethernet Port to a Hub Status LED DescriptionsT1 Link 10BT LinkModel 2720/I Loop V.54 & Telco DiagnosticsOperating Local Loopback LL T1/FT1 CSU/DSUQrss BIT Error Rate V.52 DiagnosticsEthernet 10BASE-T Specifications Patton NETLINK-T1 Model SpecificationsRJ-48C T1 DS0 Network Interface Female Modular Jack Signal Direction Tip Tx DataRS-232 Control Port Signals at DB-9 Connecter Patton NETLINK-T1 Model Interface PIN Assignment

2720 specifications

The Patton Electronics 2720 is a versatile and robust solution designed for various networking applications. It serves as a high-performance Ethernet over Copper (EoC) device, enabling the extension of Ethernet connectivity over existing copper lines. This product is particularly beneficial for businesses and organizations looking to enhance their network infrastructure without significant investment in new cabling.

One of the main features of the Patton 2720 is its ability to support multiple Ethernet standards, including 10/100/1000BASE-T. This flexibility allows users to seamlessly integrate the device into an existing network setup, accommodating both legacy and modern equipment. Additionally, the 2720 comes equipped with several Ethernet ports, providing multiple connection options and facilitating the integration of various network devices.

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Additionally, the Patton 2720 provides comprehensive network management capabilities, including SNMP support, which allows for remote monitoring and management of the device. This makes it an ideal choice for network administrators seeking robust oversight of their network infrastructure.

In conclusion, the Patton Electronics 2720 stands out as a reliable and feature-rich Ethernet over Copper solution, ideal for businesses looking to optimize their network performance while minimizing costs. Its combination of advanced technologies, flexible connectivity options, and ease of use make it a compelling choice for a wide range of applications.