Digital Signal 1
From Wikipedia, the free encyclopedia
Digital signal 1 (DS1, also known as T1, sometimes "DS-1") is a T-carrier signaling scheme devised by Bell Labs.[1] DS1 is a widely used standard in telecommunications in North America and Japan to transmit voice and data between devices. E1 is used in place of T1 outside of North America, Japan, and South Korea. Technically, DS1 is the logical bit pattern used over a physical T1 line; however, the terms "DS1" and "T1" are often used interchangeably.
A DS1 circuit is made up of twenty-four 8-bit channels (also known as timeslots or DS0s), each channel being a 64 kbit/s DS0 multiplexed carrier circuit[2]. A DS1 is also a full-duplex circuit, which means the circuit transmits and receives 1.544 Mbit/s concurrently. A total of 1.536 Mbit/s of [2] bandwidth is achieved by sampling each of the twenty-four 8-bit DS0s 8000 times per second. This sampling is referred to as 8-kHz sampling (See Pulse-code modulation). An additional 8 kbit/s of overhead is obtained from the placement of one framing bit, for a total of 1.544 Mbit/s, calculated as follows:
Contents |
[edit] DS1 frame synchronization
Frame synchronization is necessary to identify the timeslots within each 24-channel frame. Synchronization takes place by allocating a framing, or 193rd, bit. This results in 8 kbit/s of framing data, for each DS1. Because this 8-kbit/s channel is used by the transmitting equipment as overhead, only 1.536 Mbit/s is actually passed on to the user. Two types of framing schemes are Super Frame (SF) and Extended Super Frame (ESF). A Super Frame consists of twelve consecutive 193-bit frames, whereas an Extended Super Frame consists of twenty-four consecutive 193-bit frames of data. Due to the unique bit sequences exchanged, the framing schemes are not compatible with each other. These two types of framing (SF and ESF) use their 8 kbit/s framing channel in different ways.
[edit] SF framing
In SF Framing, aka Super Frame, the framing channel is divided into two channels of 4 kbit/s each. One channel is for terminal frame alignment; the second is used to align the signaling frames. The terminal frame and signaling frame bits are interleaved, rather than consecutive (they are switched in Figure 2). (correction per ANSI T1.403 Section 7.2 "A frame is a set of 192 digit time-slots for the information payload preceded by one digit time-slot containing the framing (F) bit, for a total of 193 digit time-slots." Meaning the first bit of the frame is a framing bit and not the last bit.)
The terminal frame alignment channel is carried in odd-numbered frames inside the super frame and occurs with the DS0 channel synchronization. Since the framing bits occur only once per frame, in the 193rd position, the bit placement of each DS0 can be calculated. After the framing bit is sensed, the first DS0 timeslot is taken as the next 1-8 bits. Timeslot 2 is bits 9-16, timeslot 3 is 17-24, through to timeslot 24. See Figure 1. The Terminal frame alignment pattern is carried in odd-numbered frames, inside the super frame, and consists of alternating 1s and 0s: 1–0–1–0–1–0.
Signaling frame alignment channel is carried in even-numbered frames inside the super frame and is used for signaling frame alignment. The signaling frame alignment pattern consists of a 0–0–1–1–1–0. Signaling frames are identified by the framing signal's transition from 1 to 0 and from 0 to 1; thereby frames six and twelve carry signaling information. See Figure 2.
The SF format uses bit robbing to pass signaling information. Bit robbing modifies the least significant bit in each user data timeslot twice per Super Frame. (See also A&B). The two modified frames are the sixth (A) and the twelfth (B). Using two bits, four possible signaling states can be passed in each direction (0–0, 0–1, 1–0, 1–1). In order for A/B signaling to work, the exact placement of the bits must be known by both sides. Information on the frame sequence is necessary to "pick out" the A and B bits. Channel information must also be known in order to pick out the last bit of each channel. If the proper alignment (timing) did not occur, the wrong bit could be modified or read as the robbed bit. This method of signaling is also commonly referred to as Channel Associated Signaling or CAS. See Figure 2.
The SF format is also known as D4 framing and D3/D4 framing format.
[edit] ESF framing
In ESF, aka Extended Super Frame, twenty-four frames make up the (extended) super frame. ESF divides the 8 kbit/s framing channel into three segments. The frame pattern uses 2 kbit/s, and a Cyclic redundancy check (CRC) uses 2 kbit/s. The remaining 4 kbit/s make up an administrative data link (DL) channel. The framing pattern occupies the 4th, 8th, 12th, 16th, 20th and 24th frames. The pattern consists of a 0–0–1–0–1–1 sequence. This is the only pattern repeated in the ESF format. See Figure 3.
The CRC algorithm checks a known segment of data and adds the computed value to it. The combined data and CRC blocks are both transmitted. The receive circuitry will run the same CRC algorithm against the data portion and compare the calculation to the transmitter's CRC value. In this manner, corrupted data can be flagged as "CRC errors". The CRC checksum is passed in the 2nd, 6th, 10th, 14th, 18th, and 22nd frames. (See also Error-correcting code).
The administrative channel provides a means to communicate within the DS1 stream (sub-channel). Statistics on CRC errors can be requested and sent from one end to another. The data channel occupies the twelve odd numbered frames. Signaling and other information passes over this channel. Provisions in the ESF standard would allow the normal A/B bit robbed signal to be enhanced. The A/B bits can be extended to four bits (ABCD). This provides 16 distinct states. An improvement from A/B, which provides 4. To overcome incompatibility with A/B signaling, equipment repeats the A&B bits (e.g. C = A and D = B). These additional signaling bits will offer new features as equipment is built to support it.
CRC errors can be detected and counted in at least one of four different registers. The registers are for transmit (in and out) and receive (in and out). Using recovered CRC data, it is possible to segment and isolate the direction of problems.
[edit] Connectivity and Alarms
This section does not cite any references or sources. Please help improve this article by adding citations to reliable sources (ideally, using inline citations). Unsourced material may be challenged and removed. (September 2008) |
Connectivity refers to the ability of the digital carrier to carry customer data from either end to the other. In some cases, the connectivity may be lost in one direction and maintained in the other. In all cases, the terminal equipment, i.e., the equipment that marks the endpoints of the DS1, defines the connection by the quality of the received framing pattern.
[edit] Alarms
Alarms are normally produced by the receiving terminal equipment when the framing is compromised. There are three defined alarm states, identified by a legacy color scheme: red, yellow and blue.
Red alarm indicates the alarming equipment is unable to recover the framing reliably. Corruption or loss of the signal will produce “red alarm.” Connectivity has been lost toward the alarming equipment. There is no knowledge of connectivity toward the far end.
Yellow alarm indicates reception from the far end of a data or framing pattern that reports the far end is in “red alarm.” Red alarm and yellow alarm states cannot exist simultaneously on a single piece of equipment because the “yellow alarm” pattern must be received within a framed signal. For ESF framed signals, all bits of the Data Link channel within the framing are set to data “0”; the customer data is undisturbed. For D4 framed signals, the pattern sent to indicate to the far end that inbound framing has been lost is a coercion of the framed data so that bit 2 of each timeslot is set to data “0” for three consecutive frames. Although this works well for voice circuits, the data pattern can occur frequently when carrying digital data and will produce transient “yellow alarm” states, making ESF a better alternative for data circuits.
Blue alarm indicates a disruption in the communication path between the terminal equipment. Communication devices, such as repeaters and multiplexers must see and produce line activity at the DS1 rate. If no signal is received that fills those requirements, the communications device produces a series of pulses on its output side to maintain the required activity. Those pulses represent data “1” in all data and all framing time slots. This signal maintains communication integrity while providing no framing to the terminal equipment. The receiving equipment displays a “red alarm” and sends the signal for “yellow alarm” to the far end because it has no framing, but at maintenance interfaces the equipment will report “AIS” or Alarm Indication Signal. AIS is also called “all ones” because of the data and framing pattern.
These alarm states are also lumped under the term Carrier Group Alarm (CGA). The meaning of CGA is that connectivity on the digital carrier has failed. The result of the CGA condition varies depending on the equipment function. Voice equipment typically coerces the robbed bits for signaling to a state that will result in the far end properly handling the condition, while applying an often different state to the customer equipment connected to the alarmed equipment. Simultaneously, the customer data is often coerced to a 0x7F pattern, signifying a zero-voltage condition on voice equipment. Data equipment usually passes whatever data may be present, if any, leaving it to the customer equipment to deal with the condition.
[edit] Real world use
Before the jump in Internet traffic in the mid 1990s, DS1s were found mostly in larger businesses and telephone company central offices as a means to transport voice traffic between locations. DS1s have been and still are the primary way cellular phone carriers connect their central office switches (MSCs) to the cell sites deployed throughout a city.
Today, many smaller companies often use an entire DS1 for Internet traffic, providing 1.544 Mbit/s of shareable synchronous connectivity (allowing for 1.536 Mbit/s of usable traffic, and 8 kbit/s of framing overhead). However, DS1 can be ordered as a channelized circuit, and any number of channels can be reserved for non-data (for example, voice) traffic.
Many radio stations also use this technology in their broadcasting. A T1 telephone line can be used as a link to convey the broadcast audio from the studio to the transmitter/tower site, a distance that can be quite a few miles in length. T1-based solutions, as opposed to IP-based, remain very attractive to broadcasters because the data is transported in effective real-time.
[edit] Inband T1 versus T1 PRI
Additionally, for voice T1s there are two types: so-called "plain" or Inband T1s and PRI (Primary Rate Interface). While both carry voice telephone calls in similar fashion, PRIs are commonly used in call centers and provide not only the 23 actual usable telephone lines (Known as "B" channels) but also a 24th line that carries signaling information (Known as the "D" channel for Data[3].) This special "D" channel carries: Caller ID (CID) and Automatic Number Identification (ANI) data (commonly referred to in industry parlance as "signaling data"), required channel type (usually a B channel), call handle, DNIS info, requested channel number and a request for response[4].
Inband T1s are also capable of carrying CID and ANI information if they are configured by the carrier to do so but PRI's handle this as a standard and thus the PRI's CID and ANI information has a much better chance of getting through to the destination. While an Inband T1 seemingly has a slight advantage due to 24 lines being available to make calls (as opposed to a PRI that has 23), each channel in an Inband T1 must perform its own set up and tear-down of each call. A PRI uses the 24th channel as a data channel to perform all the overhead operations of the other 23 channels (including CID and ANI). So even though an Inband T1 has 24 channels, the 23 channel PRI can actually dial more calls faster because of the dedicated 24th data (also called "D") signaling channel.
[edit] Origin of Name
This section does not cite any references or sources. Please help improve this article by adding citations to reliable sources (ideally, using inline citations). Unsourced material may be challenged and removed. (November 2007) |
The name T1 came from the carrier letter assigned by AT&T to the technology. Essentially, the "T" is a part number that was assigned by AT&T. Just as there is the generally known L-carrier and N-carrier systems, T-carrier was next letter available and T1 is the first level in the hierarchy. DS-1 meant "Digital Service - Level 1", and had to do with the service to be sent (originally 24 digitized voice channels over the T1). The terms T1 and DS1 have become synonymous and include a plethora of different services from voice to data to clear-channel pipes. The line speed is always consistent at 1.544 Mbit/s, but the payload can vary greatly.
[edit] Examples
The global telephone network (also known as the Public Switched Telephone Network or PSTN).
[edit] Notes and references
- ^ "How Bell Ran in Digital Communications" September 1996, webpage: BYTE-Bell: Bell Labs scientists developed a time-division multiplexing scheme, T1.
- ^ Just Circuits - T1 Made Simple [1]
- ^ Versadial, Call recording encyclopedia, last accessed 19 Apr 2007
- ^ Newton, H: "Newton's telecom dictionary", page 225. CMP books, 2004