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Digital Signal 3
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Digital Signal 3 (DS3 or T3 line) is a digital signal level 3 T-carrier. The signal rate for this type of signal is 44.736 Mbit/s (45 Mb). It can transport 28 DS1 level signals within its payload. It can transport 672 DS0 level channels within its payload.[1]

Such circuits are the usual kind between telephony carriers, both wired and wireless, and typically by OC1[citation needed] optical connections.

Cabling

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DS3 interconnect cables must be made with true 75-ohm coaxial cable and connectors. Cables or connectors which are 50 ohms or which significantly deviate from 75 ohms will result in signal reflections which will lower the performance of the connection, possibly to the point of not working. GR-139-CORE, Generic Requirements for Central Office Coaxial Cable, defines type 734 and 735 cables for this application. Due to losses, there are differing distance limitations for each type of cable. Type 734 has a larger center conductor and insulator for lower losses for a given distance. The BNC connectors are also very important as are the crimping and cable stripping tools used to install them. Trompeter, Cannon, Amphenol, Kings, and Canare make some of the most reliable 75 ohm connectors known. RG-6 or even inexpensive RG-59 cable may work temporarily when properly terminated, though it does not meet telephony technical standards. Type 735 26 AWG is used for interconnects up to 225 feet, and Type 734 20 AWG is used for interconnects up to 450 feet.

Pricing

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DS3 service is provided to businesses in the United States through incumbent local exchange carrier and competitive local exchange carrier communication providers. The price, much like a T1 (or DS1) line, has two primary components: the loop (which is distance-sensitive) and the port (or the price the carrier charges to access the internet through their proprietary network).

See also

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Digital Signal 3

View on Grokipedia
from Grokipedia
Digital Signal 3 (DS3), also known as a T3 line, is a high-capacity telecommunications standard for transmitting digital data at a rate of 44.736 megabits per second (Mbps), enabling the transport of large volumes of voice, video, and data traffic across point-to-point circuits. Developed by AT&T in the 1960s as part of the T-carrier system, DS3 multiplexes 28 lower-level Digital Signal 1 (DS1) channels, each operating at 1.544 Mbps, plus overhead for framing and synchronization, to achieve its aggregate bandwidth. This technology has historically supported backbone infrastructure for wide-area networks, including internet service providers and enterprises requiring dedicated, high-speed connectivity, though it has largely been supplanted by fiber-optic alternatives like SONET and Ethernet in modern deployments. DS3 signals are typically delivered over coaxial cable or fiber using specific framing formats, such as C-bit parity for error detection and performance monitoring, ensuring reliable transmission in legacy telecommunication environments.

Overview

Definition

Digital Signal 3 (DS3) is a standardized digital signal that constitutes the third level in the North American system, also known as a T3 line. This system forms part of the (PDH), which enables the multiplexing and aggregation of multiple lower-rate digital signals into higher-capacity streams for transmission over telecommunications networks. The primary purpose of DS3 is to facilitate high-capacity digital transmission of voice, data, and video services by combining signals from lower levels, such as 28 DS1 (T1) channels, into a single efficient pathway. As specified in the digital hierarchy formats standard, DS3 ensures across interconnected networks by defining the structural parameters necessary for reliable signal transport.

Position in Digital Hierarchy

In the North American system, Digital Signal 3 (DS3) occupies the third level of the digital hierarchy, serving as a stage that aggregates 28 DS1 signals, each comprising 24 DS0 channels at 64 kbps, for a total of 672 voice or data channels. This structure builds upon lower levels, where DS1 operates at 1.544 Mbps and DS2 at 6.312 Mbps, enabling DS3 to deliver a line rate of 44.736 Mbps for efficient trunking of multiple lower-rate signals. Within the broader (PDH), DS3 positions between DS2 and the higher DS4 level at 274.176 Mbps, facilitating scalable aggregation in plesiochronous multiplexing environments where timing variations are managed through at intermediate stages. Internationally, DS3 finds a partial equivalent in the European hierarchy's E3 level, which operates at 34.368 Mbps and multiplexes 16 E1 signals or 512 E0 channels, though the differing rates and framing prevent direct compatibility without conversion equipment. DS3's primary role in legacy telecommunications networks involves enabling the aggregation of numerous lower-speed circuits into high-capacity trunks, supporting backbone transport for voice, data, and video services in pre-SONET/SDH infrastructures.

Technical Specifications

Signal Rate and Capacity

The Digital Signal 3 (DS3) operates at a nominal bit rate of 44.736 Mbps, commonly rounded to 45 Mbps in informal references. This rate establishes the fundamental transmission speed for high-capacity digital signals in the North American T-carrier hierarchy. The DS3 signal achieves synchronous operation by multiplexing 28 DS1 signals, each running at 1.544 Mbps, with added stuffing bits to align timing and compensate for rate differences in the asynchronous lower levels. The resulting payload capacity is 43.008 Mbps, which supports up to 672 voice channels at 64 kbps each (derived as 28 DS1 × 24 DS0 channels per DS1). This aggregation from DS1 rates enables efficient transport of voice or data traffic in a channelized format. Overhead accounts for approximately 1.728 Mbps of the total , dedicated to framing, , and maintenance functions across the DS1, DS2, and DS3 levels, including bits and parity checks.

Framing Formats

The DS3 signal employs two primary framing formats: the original M13 asynchronous and the later C-bit parity synchronous format, both defined within the ANSI T1.107 standard for digital hierarchy formats. The M13 format multiplexes seven DS2 signals into a DS3 by interleaving their bits asynchronously, requiring to accommodate rate differences between the aggregate DS2 rate and the fixed DS3 line rate of 44.736 Mbps. In the M13 format, the frame, known as an M-frame, consists of seven subframes, each comprising eight blocks of 85 bits, for a total of 4760 bits per frame at a rate of approximately 9400 per second. Framing (F) bits occupy one position per block (85 F-bits total per frame), with a fixed of 1001 repeated in specific blocks (2, 4, 6, and 8 of each subframe) to enable frame alignment and . The 21 C-bits (three per subframe) serve as stuffing indicators: a majority of ones signals a stuffed bit in the following data position to adjust for asynchronous DS2 inputs, while a majority of zeros indicates valid data, ensuring just-in-time without . This asynchronous approach introduces variable overhead due to , typically resulting in less than full channel utilization. The C-bit parity format maintains the same basic frame structure as M13—seven subframes of eight 85-bit blocks each, totaling 4760 bits—but operates synchronously, assuming the seven DS2 signals are bit-aligned to the DS3 clock, eliminating the need for bit stuffing at the DS3 level. The 85 F-bits retain their alignment role, with the pattern 1001 in subframes 1 through 6; in subframe 7, the F-bits follow the same pattern. The three M-bits in the first bit position of block 1 in subframes 5, 6, and 7 provide M-frame alignment using the repeating pattern "010" across every seven frames. The 21 C-bits (three per subframe) are repurposed for various control and monitoring functions: these include far-end block error (FEBE) indicators for performance monitoring, far-end alarm and control (FEAC) signaling for alarms (using six bits across subframes 2 and 3), a path parity bit for error detection across the entire frame, and reserved bits for in-band data links, enabling enhanced and end-to-end diagnostics. Standardized in ANSI T1.107 revisions during the late , the C-bit parity format gained prominence in the 1990s as networks shifted toward synchronous operation, offering superior error detection and monitoring capabilities over M13 while achieving near-constant 99.9% channel utilization by freeing C-bits from stuffing duties. This transition facilitated better scalability in backbones, with C-bit becoming the predominant format for new DS3 deployments.

Line Encoding

Line encoding for Digital Signal 3 (DS3) transmission employs bipolar return-to-zero (BPRZ), also known as alternate mark inversion (AMI), as the foundational scheme, where logical ones are represented by alternating positive and negative voltage pulses, and zeros by the absence of a pulse. This base encoding ensures a balanced signal with no DC component under ideal conditions but is susceptible to long sequences of zeros, which can degrade clock recovery and cause baseline wander. To address these issues, DS3 uses bipolar with 3-zero substitution (B3ZS) as a modification to the basic BPRZ/AMI format, maintaining a minimum density of ones while preserving compatibility with AMI receivers. In B3ZS, every occurrence of four consecutive zeros in the data stream is replaced by a specific bipolar violation pattern: either 000V, where V is a pulse of the same polarity as the previous mark (violation of alternation), or B00V, where B is a pulse of the opposite polarity to the previous mark (violation) and V is a pulse of the same polarity as the previous mark (another violation), with the choice made to balance violations and ensure no more than three consecutive zeros. This substitution ensures no more than three consecutive zeros, thereby reducing DC wander and facilitating reliable clock extraction at the receiver. The deliberate introduction of bipolar violations in B3ZS not only supports but also enhances detection compared to plain AMI, as receivers can identify unintended violations as transmission errors. This improvement enables robust DS3 signal propagation over for distances up to approximately 100 meters without requiring regeneration, depending on cable quality and equalization. B3ZS is specified in ANSI T1.107 for DS3 interfaces, ensuring in networks.

Physical Layer

Transmission Media

The primary transmission medium for DS3 signals is 75-ohm , with standard types such as 728A (up to approximately 30 meters or 100 feet), 734A (up to 137 meters or 450 feet), and 735A (up to 69 meters or 225 feet) suitable for short-haul runs without , depending on cable quality and environmental factors. Specialized variants like Belden 735A provide similar performance for DS3 applications, supporting distances of approximately 69 meters for mini-coax configurations. These cables ensure reliable propagation of the 44.736 Mbps signal while maintaining to minimize reflections. For short-haul transmission, DS3 signals are transmitted at ±0.775 V peak , with receivers capable of handling up to 15 dB of cable loss to preserve over the cable length. This specification aligns with line build-out (LBO) requirements that simulate cable loss for consistent receiver performance. In long-haul scenarios over , repeaters are required every 183 meters (600 feet) to regenerate the signal and counteract . For distances beyond practical limits, DS3 signals are frequently converted to optical formats via CSU/DSU interfaces for transmission over optic or media, mitigating range constraints. Although designed for terrestrial , DS3 over remains susceptible to , which can introduce noise and errors in electrically noisy environments.

Interfaces and Connectors

The primary interface for Digital Signal 3 (DS3) connections utilizes the BNC (Bayonet Neill-Concelman) connector, designed for unbalanced 75-ohm to ensure reliable high-frequency signal transmission in environments. This connector type supports the DS3's 44.736 Mbps by providing a secure, twist-lock mechanism that minimizes signal loss at the physical connection point. A Channel Service Unit/Data Service Unit (CSU/DSU) is mandatory at the network for DS3 deployments, serving as the interface between and the carrier's network. The CSU component handles line conditioning, surge protection, and testing for diagnostics, while the DSU manages data formatting and to maintain . DS3 interfaces adhere to ANSI T1.102-1993 (R2005), which specifies the electrical characteristics including voltage levels, impedance, and connector pinouts for the North American digital hierarchy at the DS3 level. Additionally, compliance with Telcordia GR-1089-CORE ensures electromagnetic interference () immunity, protecting against conducted and radiated disturbances in typical network equipment bays. In compact or high-density setups, such as certain Cisco ONS 15454 cards, SMB (SubMiniature B) connectors may be employed as an alternative to BNC for DS3 interfaces, offering a smaller footprint while maintaining 75-ohm impedance. Adapters are frequently used to integrate DS3 with SONET optical systems or Ethernet multiplexers, facilitating hybrid network architectures. These interfaces are compatible with coaxial transmission media like 734A or 735A cables for short-haul connections.

History

Development Origins

The Digital Signal 3 (DS3), also known as T3, was developed by Bell Laboratories in the early 1960s as a higher-level extension of the T1 (DS1) system, which had been introduced in 1962 for long-haul pulse-code modulation (PCM) voice transmission over copper wires. The DS1 system itself originated from Bell Labs' efforts in the late to digitize voice signals, encoding 24 channels at 1.544 Mbps to support efficient multiplexing. This development was motivated by the surging demand for inter-office trunk capacity in the post-World War II era, as telephone traffic exploded due to economic growth and increased urbanization, straining existing analog infrastructure. aimed to create a scalable digital hierarchy that could aggregate multiple DS1 signals—specifically 28 of them—into a single 44.736 Mbps DS3 stream, enabling the transport of 672 simultaneous voice channels to meet these needs. As part of the broader system, DS3 represented a shift from analog (FDM) to digital techniques, which minimized interference inherent in analog systems and facilitated through bit-level redundancy. This transition improved signal integrity over long distances, particularly on and links, laying the groundwork for a more reliable national backbone. An early milestone came in the 1970s, when began commercial rollout of DS3 services for long-distance backbone networks, initially via relays between major U.S. cities to handle high-volume toll traffic.

Standardization and Deployment

The standardization of Digital Signal 3 (DS3) was formalized through the (ANSI) T1.107 specification, initially published in 1988 to define DS3 framing formats such as M23 , with a 1995 revision incorporating C-bit parity for enhanced error detection and maintenance capabilities. This shift to C-bit parity in the revised standard allowed for better overhead utilization, including application identification and path monitoring, improving in digital hierarchies. Complementing ANSI T1.107, the Bellcore (now Telcordia) GR-499-CORE document outlined generic requirements for transport systems, including DS3 electrical interfaces, impedance criteria, and specifications to ensure network compatibility and reliability. DS3 deployment began gaining traction in the as a backbone technology for carriers, enabling high-capacity voice and data transmission over and early links. Its adoption peaked in the , particularly for early infrastructure, where DS3 circuits provided essential bandwidth for interexchange carriers and emerging data services. The 1984 divestiture of accelerated DS3 proliferation by deregulating the market, allowing regional Bell operating companies and private entities to build independent networks using systems like DS3 for cost-effective, high-speed connectivity. However, deployment declined post-2000 as fiber-optic technologies, including dense wavelength-division multiplexing, offered superior capacity and efficiency, rendering DS3 less viable for new installations. In the , DS3 evolved through integration with (SONET), where a single DS3 signal is mapped directly into the Synchronous Transport Signal level 1 () payload for optical transmission, facilitating a smooth transition to fiber-based hierarchies without altering the underlying DS3 structure. As of 2025, DS3 persists in legacy systems, particularly for rural connectivity and backup links in areas lacking modern infrastructure, supported by ongoing regulatory frameworks for TDM services. This enduring role underscores DS3's foundational contributions, originally developed by in the , to scalable digital transport.

Applications

Telecommunications Uses

Digital Signal 3 (DS3) serves as a foundational component in traditional infrastructure, primarily for aggregating up to 672 individual voice channels into a single high-capacity circuit operating at 44.736 Mbps. This capability, achieved by combining 28 DS1 signals—each supporting 24 DS0 voice channels at 64 kbps—enables efficient voice trunking for inter-exchange carriers, where large volumes of calls are routed between central offices over long distances. Telecommunications providers leverage DS3 for these trunks to consolidate from multiple lower-rate lines, reducing operational complexity and costs in backbone networks. Additionally, DS3 connects private branch exchanges (PBX) in enterprise environments, allowing organizations to handle substantial internal and external voice without relying on fragmented lower-speed . DS3 circuits further support critical signaling protocols essential for modern call management, including Signaling System No. 7 (SS7) for control and ISDN (PRI) for integrated voice and data services. SS7 enables reliable call routing, setup, and teardown across public switched telephone networks (PSTN) by dedicating time slots within the DS3 payload for signaling messages, independent of the voice channels. ISDN PRI, operating over DS3, provides 23 bearer channels (B-channels) for voice or data plus one data (D) channel for signaling per DS1 sub-stream, supporting features like and in PRI configurations. These capabilities ensure seamless integration with legacy PSTN elements, where DS3 acts as the for PRI and SS7 to maintain compatibility in hybrid voice systems. In broadcasting applications, DS3 facilitates the transport of compressed standard-definition (SD) video for contribution feeds, where multiple DS3 streams are combined to meet the bandwidth demands equivalent to 270 Mbps (SDI) signals. This approach allows remote production sites to deliver video to central studios or headends, particularly useful for live events requiring low-latency transmission. Broadcasters historically adopted DS3 for such feeds due to its synchronous nature and reliability over dedicated lines, though it often involves several circuits to accommodate the full SD video rate. As of 2025, DS3 persists in legacy roles, notably for microwave links in remote or underserved areas where fiber deployment remains impractical. These point-to-point microwave systems extend DS3 connectivity over line-of-sight paths, supporting voice services in rural regions or disaster-prone zones with limited . DS3 also functions as a option in hybrid networks, providing redundant TDM paths alongside IP-based alternatives to ensure service continuity during outages. This enduring utility underscores DS3's role in bridging older hierarchies with evolving telecom demands.

Data and Internet Services

Digital Signal 3 (DS3) provides dedicated for enterprises, delivering symmetric bandwidth of up to 45 Mbps suitable for applications such as web hosting, virtual private networks (VPNs), and large file transfers. This consistent, high-speed connection ensures reliable performance for mission-critical data operations, where symmetrical and speeds minimize latency in bandwidth-intensive tasks. Enterprises leverage DS3 lines to maintain secure, uninterrupted connectivity to the , particularly in scenarios requiring dedicated rather than shared bandwidth. In data networking, DS3 facilitates aggregation by bundling multiple lower-speed T1 lines—up to 28 DS1 circuits—enabling Service Providers (ISPs) to efficiently scale capacity for broader distribution. Within data centers, DS3 serves as a robust link for and storage connectivity, aggregating traffic from multiple sources to support high-volume data replication and redundancy. This aggregation capability stems from DS3's (TDM) architecture, which integrates disparate streams into a single 44.736 Mbps channel for efficient transport. As of 2025, DS3 remains cost-effective for mid-sized businesses, with monthly service fees ranging from approximately $1,000 to $5,000 depending on location and provider—lower in urban metros ($1,000–$2,500) and higher in rural areas ($3,000–$5,000+). However, its appeal is declining relative to fiber-optic alternatives, which offer higher speeds at lower per-Mbps costs, though DS3 supports Ethernet integration via converters for compatibility with modern IP networks. Beyond core access and aggregation, DS3 enables backups and remote site connectivity in environments where deployment is impractical or delayed, providing a dedicated pathway for and off-site replication. Its reliability makes it viable for bridging gaps in , ensuring continuous data flow to remote locations without reliance on shared consumer-grade services.

Comparisons

With Lower T-Carrier Levels

Digital Signal 3 (DS3) provides a line rate of 44.736 Mbps, representing a substantial increase over the lower levels, including (DS1) at 1.544 Mbps and Digital Signal 2 (DS2) at 6.312 Mbps. DS1 accommodates 24 digital voice channels at 64 kbps each, while DS2 multiplexes four DS1 signals to support 96 channels. In the hierarchy, DS3 aggregates seven DS2 signals or, equivalently, 28 DS1 signals, enabling it to handle up to 672 voice channels. This capacity scaling comes with approximately 3.4% overhead due to asynchronous and framing, as the combined rate of 28 DS1 signals (43.232 Mbps) is padded with to fit the fixed DS3 frame structure. The process involves two stages: first, four DS1s per DS2 with minimal stuffing (about 0.025% per DS1), followed by seven DS2s into DS3, where additional framing bits (56 per frame at 8 kHz) contribute to the overall line rate. As a result, DS3 delivers roughly 28 times the bandwidth of a single DS1 but demands more sophisticated equipment, serving as a natural migration path for networks outgrowing DS1 capacity. In terms of use cases, DS1 is primarily deployed for end-user access lines, such as connecting business PBX systems or early internet services to the local carrier network. DS2 functions mainly as an intermediate aggregation level, though it sees limited standalone deployment due to its transitional role. DS3, by contrast, targets high-volume backhaul applications, aggregating traffic from multiple DS1 lines for transport between central offices, links, or major hubs in infrastructure. This positions DS3 higher in the hierarchy for inter-facility connectivity. The payload efficiency of DS3, considering end-to-end user data (e.g., voice at 43.008 Mbps for 672 channels), reaches about 96.1% of the line rate, slightly lower than DS1's 99.5% due to cumulative multi-level and overhead bits across the .

With Optical and Modern Alternatives

Digital Signal 3 (DS3) signals, operating at a line rate of 44.736 Mbps, can be mapped into the Synchronous Transport Signal level 1 () frame of OC-1, which provides a total bit rate of 51.84 Mbps including overhead for and management. This mapping allows DS3 to leverage optical transport, but introduces additional framing overhead of approximately 7 Mbps, enabling features like error monitoring and that are absent in the plesiochronous DS3 format. OC-1 is particularly preferred over standalone DS3 for ring topologies, where bidirectional self-healing mechanisms ensure rapid fault recovery in under 50 ms, supporting reliable service over longer distances up to hundreds of kilometers on without the signal regeneration needs of copper-based DS3. In contrast to Ethernet and (GigE), DS3 delivers a of about 44 Mbps in a rigid (TDM) structure, while at 100 Mbps or GigE at 1 Gbps provides packet-switched flexibility for local and wide area networks at lower per-megabit costs. Ethernet avoids the fixed framing and challenges of DS3's TDM, allowing scalable bandwidth allocation and easier integration with IP-based services, often at half the cost or less for equivalent speeds like 50 Mbps Ethernet versus DS3. This makes Ethernet the go-to for modern LAN/WAN deployments, where DS3's lack of native packet handling limits its adaptability to variable traffic patterns. By 2025, DS3 has been largely supplanted in core networks by (MPLS) for efficient traffic engineering, Dense Wavelength Division Multiplexing (DWDM) systems offering 10 Gbps or higher per channel on , and backhaul solutions that prioritize low-latency packet transport. However, DS3 endures in legacy and hybrid environments, such as short-haul connections under 1 km, where its implementation over remains significantly less expensive than OC-3 optical services due to avoided infrastructure costs. A key limitation of DS3 stems from its (PDH) design, where tributary signals operate at nominally similar but not perfectly synchronized rates, leading to accumulated and that disrupts timing in modern synchronous networks. In comparison, Synchronous Digital Hierarchy (SDH) and employ a unified clock reference, minimizing and enabling seamless integration across diverse equipment without the desynchronization issues inherent to PDH-based DS3.

References

  1. https://www.lenovo.com/us/en/glossary/digital-signal-3/
  2. https://www.tvtechnology.com/opinions/the-enduring-legacy-of-ds3
  3. https://www.bandwidth.com/glossary/digital-signal-3-ds3/
  4. https://www.centurylink.com/wholesale/pcat/ds3.html
  5. https://glossary.atis.org/glossary/t-carrier/
  6. https://www.albedotelecom.com/src/lib/WP-E1-T1-PDH.pdf
  7. https://webstore.ansi.org/standards/atis/ansit11071995
  8. https://www.oreilly.com/library/view/t1-a-survival/0596001274/ch04.html
  9. https://xanthus-consulting.com/IntelliGrid_Architecture/New_Technologies/Tech_Digital_Signal_%28DSx%29%2C_Time-division_multiplexing%2C_the_T-carr.htm
  10. https://zytrax.com/tech/data_rates.htm
  11. https://www.technologyuk.net/telecommunications/communication-technologies/plesiochronous-digital-hierarchy.shtml
  12. https://www.ad-net.com.tw/what-is-ds3t3-and-e3-and-what-are-the-differences-between-t3ds3-and-e3/
  13. https://www.rfc-editor.org/rfc/rfc2496.html
  14. https://www.federalregister.gov/documents/2020/01/06/2019-27607/modernizing-unbundling-and-resale-requirements-in-an-era-of-next-generation-networks-and-services
  15. https://www.broadband-forum.org/download/af-phy-0054.000.pdf
  16. https://www.t3rex.com/articles/ds3t3.php
  17. https://classes.engineering.wustl.edu/2012/fall/ese571/DS3%20Fundamentals.pdf
  18. https://www.dialogic.com/webhelp/csp1010/8.4.1_ipn3/ds3_chap_-_technology_overview.htm
  19. https://www.cisco.com/c/en/us/support/docs/asynchronous-transfer-mode-atm/atm-signaling/10417-atmds-framing.html
  20. https://www.michael-henderson.us/Papers/Framing%28rev%20b%29.pdf
  21. https://yugten.files.wordpress.com/2009/06/t3fundamentals.pdf
  22. https://www.analog.com/media/en/technical-documentation/data-sheets/ds3171-ds3174.pdf
  23. https://www.utdallas.edu/~torlak/courses/ee4367/lectures/CodingI.pdf
  24. https://www.centurylink.com/techpub/77324/77324.pdf
  25. https://www.maxlinear.com/ds/75l02_v103_121305.pdf
  26. https://datatracker.ietf.org/doc/rfc1407/
  27. https://www.flukenetworks.com/blog/cabling-chronicles/coax-cable-you-might-just-need-test-it
  28. https://www.belden.com/products/cable/coax-triax-cable/ds3-ds4-cable/735a8
  29. https://www.belden.com/products/cable/coax-triax-cable/ds3-ds4-cable/735a1
  30. https://www.analog.com/media/en/technical-documentation/data-sheets/ds3177.pdf
  31. https://www.analog.com/media/en/technical-documentation/data-sheets/ds3150.pdf
  32. https://www.data-connect.com/ds1_ds3.htm
  33. https://www.ctcu.com/en/product/FRM220-DS3_E3.html
  34. https://www.belden.com/blog/Going-the-Distance-with-Serial-Digital-Coax
  35. https://lv.mouser.com/datasheet/2/643/tromp_ds3_telco_catalog-739102.pdf
  36. https://www.showmecables.com/bnc-male-crimp-connector-belden-734a1-ds3
  37. https://webstore.ansi.org/standards/atis/ansit11021993r2005
  38. https://www.china-gauges.com/Uploads/download/5723034d2f8e0.pdf
  39. https://www.cisco.com/en/US/docs/optical/15000r4_0/15454/sonet/reference/guide/r40eecrd.html
  40. https://www.cisco.com/c/en/us/td/docs/optical/15000r7_0_1/15454/sonet/procedure/guide/701procr/r701dlp0.pdf
  41. https://www.stonewallcable.com/734a-coax-cable-bnc-plug-bnc-plug-5576
  42. https://calhoun.nps.edu/bitstream/handle/10945/23691/historicalovervi00jens.pdf?sequence=3
  43. https://www.historyofinformation.com/detail.php?id=3364
  44. https://ethw.org/Milestones:Bell_Telephone_Laboratories%2C_Inc.%2C_1925-1983
  45. https://www.analog.com/media/en/technical-documentation/data-sheets/ds3141-ds3144.pdf
  46. https://telecom-info.njdepot.ericsson.net/site-cgi/ido/docs.cgi?ID=SEARCH&DOCUMENT=GR-499
  47. https://historyofcomputercommunications.info/section/1.5/Institutional-Change-in-Communications-Deregulation-and-Break-up-of-AT&T/
  48. https://docs.fcc.gov/public/attachments/FCC-17-43A1.pdf
  49. https://www.tek.com/en/documents/primer/sonet-telecommunications-standard-primer
  50. https://www.federalregister.gov/documents/2021/01/08/2020-25254/modernizing-unbundling-and-resale-requirements-in-an-era-of-next-generation-networks-and-services
  51. https://pld.cs.luc.edu/telecom/documents/DS3fundamentals.pdf
  52. https://www.dcbnet.com/notes/9611t1.html
  53. https://ds3.solveforce.com/
  54. https://www.oriontelecom.com/echo_canceller/ds3/ds3_echo_canceller.html
  55. https://www.pulsesupply.com/gateway-products/telcobridges-tmg3200-ds3
  56. https://telcobridges.com/products/signaling-gateways-tsig/tsg3200-tsig-signaling-sigtran-gateway/
  57. https://www.tvtechnology.com/opinion/cloud-production-assessment-for-media
  58. https://www.tccomm.com/Literature/Literature/Ethernet-Network-Case-Studies/Ethernet-Over-DS-3
  59. https://www.microwavejournal.com/articles/8713-teton-standardizes-on-exalt-microwave-radio-systems
  60. https://www.meter.com/resources/t3-line
  61. https://www.bsimplify.com/ds3-pricing-t3-internet-bandwidth-costs/
  62. https://www.federalregister.gov/documents/2017/06/02/2017-10713/business-data-services-in-an-internet-protocol-environment-technology-transitions-special-access-for
  63. https://www.business.att.com/content/dam/attbusiness/collateral/EIS-Section-C-GS00Q17NSD3000.pdf
  64. https://rbr.business.rutgers.edu/sites/default/files/documents/rbr-020107.pdf
  65. https://www.valiantcom.com/converters/ethernet-ds3.html
  66. https://catalogimages.wiley.com/images/db/pdf/078031168X.excerpt.pdf
  67. https://www.gigapackets.com/articles/gigabit-ethernet-sonet.php
  68. https://www.ethernetbuildings.com/articles/50Mbps-Ethernet-DS3.php
  69. https://www.gigapackets.com/articles/oc3bandwidth.php
  70. https://www.t1rex.com/ds3.html
  71. https://www.e1-converter.com/TechnicalLectures/differences_PDH_SONET_SDH.html
  72. https://www.geeksforgeeks.org/computer-networks/difference-between-pdh-and-sdh/
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