Original North American area codes
The original North American area codes were established by the American Telephone and Telegraph Company (AT&T) in 1947, after the demonstration of regional Operator Toll Dialing during the World War II period. The program had the goal of speeding the connecting times for long-distance calling by eliminating intermediary telephone operators. Expanding this technology for national use required a comprehensive and universal, continent-wide telephone numbering plan.
The new numbering plan established a uniform destination addressing and call routing system for all telephone networks in North America which had become an essential public service.[1] It had the eventual benefit of direct distance dialing (DDD) by telephone subscribers, a feature by which a caller may, without operator assistance, call any other user outside the local calling area (typically requiring extra digits to be dialed).
The initial Nationwide Numbering Plan of 1947 established eighty-six numbering plan areas (NPAs) that conformed mainly to existing U.S. state and Canadian provincial boundaries, though fifteen states and provinces were subdivided further. Forty NPAs were mapped to entire states or provinces. Each NPA was identified by a three-digit area code used as a prefix to each local telephone number. The United States received seventy-seven area codes, and Canada nine. The initial system of numbering plan areas and area codes was expanded rapidly during the ensuing decades, and established the North American Numbering Plan (NANP).
History
[edit]Early in the 20th century, the American and Canadian telephone industry had established criteria and circuits for sending telephone calls across the vast number of local telephone networks on the continent to permit users to call others in many remote places in both countries. By 1930, this resulted in the establishment of the General Toll Switching Plan, a systematic method, with technical specifications, for routing calls between two major classes of routing centers, Regional Centers and Primary Outlets,[2] as well as thousands of minor interchange points and tributaries. Calls were forwarded manually between stations by long-distance operators who used the method of ringdown to command remote operators to accept calls on behalf of customers. This required long call set-up times with several intermediate operators involved. When making a call, the originating party would typically have to hang up and be called back by an operator once the call was established.
The introduction of the first Western Electric No. 4 Crossbar Switching System in Philadelphia to commercial service, in August 1943,[3] automated the process of forwarding telephone calls between regional switching stations. For the Bell System this was a beginning for the ability of their long-distance operators to dial calls directly to distant telephones.[4] While automatic switching decreased the connection times from as much as fifteen minutes to approximately two minutes for calls between far-away locations, each intermediate operator still had to determine special routing codes unique to their location for each call. To make a nationwide dialing network an efficient, practical reality, a uniform nationwide numbering plan was needed so that each telephone on the continent had a unique address that could be used independently from where a call originated. Such a system is called destination routing.
With this goal, AT&T developed a new framework during the early 1940s, termed Operator Toll Dialing, which was begun by the installation of a newly developed toll switching system in Philadelphia in 1943. In 1945, the American Telephone and Telegraph Company declared this effort a major post-war project for the Bell System,[5] and proceeded with periodical communications to the general telecommunication industry via the Dial Interexchange Committee of the United States Independent Telephone Association (USITA),[6] which disseminated the project's progress to its members via industry journals and conference contributions. The planning transitioned to implementation, when Ralph Mabbs presented the results in a talk at the Fiftieth Anniversary Meeting of the Independent Telephone Association, on October 14, 1947.[7]
A fundamental requirement for the success of automated toll dialing was a new telephone numbering plan, which became known as the Nationwide Numbering Plan. This numbering plan accounted initially for seventy-seven area codes in the United States and nine in Canada. With the construction of technical infrastructure for automated toll dialing, the allocations needed to be changed in many states, adding numerous additional area codes during the next decade. By 1975, the numbering plan was known as the North American Numbering Plan, as efforts were in progress to expand the system beyond the United States and Canada.
Numbering plan requirements
[edit]Building a nationwide network in which any telephone could be dialed directly required a systematic numbering system that was easy to understand and communicate. Local telephone numbers varied greatly across the country, from two or three digits in small communities, to seven in the large cities.
By the time the Bell Laboratory engineers began efforts to involve the broader industry bodies in 1945, definite concepts had been developed for Operator Toll Dialing. A crucial requirement was the conversion of all participating telephone networks to a universal numbering plan. In 1947, Ralph Mabbs recalled the specifications for this numbering plan as follows:[7]
- A distinctive telephone number for each telephone in the United States and Canada.
- The minimum number of digits which will provide for growth and new services.
- Minimum changes in customers' numbers.
- Minimum changes in local dialing practice.
- Least cost for equipment changes.
- Minimum reference by operators to bulletins and route guides to gain speed of service advantages.
- Provisions for operators to directly reach other operators at distant toll centers.
Based on the precedent and experience with the large-city dial systems in the nation, the designers decided to direct all telephone companies in the nation to standardize the local telephone networks to seven-digit local telephone numbers before they could participate with Operator Toll Dialing. This required few or no changes in the nation's largest cities, but in the smaller communities the shorter telephone numbers had to be padded with additional digits in a transparent, easily understandable manner, so that extra digits were not always needed when dialing other local subscribers. By 1955, AT&T disseminated a formal publication of network documentation, specifications, and recommendations to the telephone industry, entitled Notes on Nationwide Dialing.[7][8][9]
Central office prefixes
[edit]Most automatic dial switching systems were designed since the early 1920s to provide service for as many as ten-thousand subscriber lines. Each of these switching systems constituted a local telephone exchange, formally known as a central office. Therefore, each telephone connected to a central office had a unique four-digit line or station number.
In larger communities that required multiple central offices to account for the service need of their population, extra digits were added to the telephone number, preceding the line number. Such extra digits were dialed when calling a telephone connected to another switching system in the same city or in a nearby community, and served as routing codes to those central offices. Central office prefixes had already been used in the cities' dial systems since the 1920s, and were typically dialed by subscribers as the initial letters of the exchange name, but only the largest of cities used three digits or letters. This practice and familiarity was preserved in the initial formulation of the new numbering plan, but was standardized to a format of using two letters and one digit in the prefix, resulting in the format 2L–5N (two letters and five numerals) for the subscriber telephone number.[9]
For most cities, this conversion required the addition of extra digits or letters to the existing central office prefix. For example, the Atlantic City, New Jersey, telephone number 4-5876 was converted to AT4-5876 during the 1950s. Complete replacement of existing prefixes was necessary in the case of conflicts with another office in the state. Duplication of central office names, or an identical mapping of two different names to digits, was not uncommon. In practice, the conversion of the nation to this numbering plan took decades to accomplish and was not complete before the alphanumeric number format was abandoned during the 1960s in favor of all-number calling (ANC).
In addition to the central offices that provided the subscriber lines for each telephone (wire centers), the toll routing system included special switching facilities that routed long-distance calls between end offices. Each of these toll offices also received an assignment of a unique three-digit toll office code. To reach another operator in another central office or toll office, an operator dialed only the office code of the destination.
Numbering plan areas
[edit]By 1945, initial concepts for a nationwide numbering plan anticipated a division of the continent into between fifty and seventy-five numbering plan areas.[10] For this size of the network, a unique two-digit code for each numbering plan area (NPA) would have been sufficient. However, AT&T wanted to preserve existing dialing practices by only dialing the local number for local calls; it was therefore necessary to distinguish the NPA codes from central office codes automatically by the switching system. Central office codes already could not have the digits 0 and 1 in either of the first two positions, because no letters were mapped to those to represent exchange names. This was the opportunity for distinction, but only when 0 or 1 were used in the second position, because switching systems already suppressed single loop interruption (corresponding to 1) automatically, and 0 was used to reach an operator or long-distance desk.[9]
Therefore, numbering plan area codes, often termed just area codes, were defined to have three digits, with the middle digit being 0 or 1. Area codes with the middle digit 0 were assigned to numbering plan areas that comprised an entire state or province, while jurisdictions with multiple numbering plan areas received area codes having 1 as the second digit. This pattern lasted only until 1956, when New Jersey's "201" was divided.
The geographic layout of numbering plan areas across the North American continent was chosen primarily according to national, state, and territorial boundaries in Canada and the United States.[7] While originally considered, no numbering plan area in the United States included more than a single state, but in Canada NPA 902 comprised all three provinces of The Maritimes in the far east. The largest states, and some states with suitable call routing infrastructure were divided into smaller entities, resulting in fifteen states and provinces that were subdivided further, creating 46 NPAs. Forty NPAs were assigned to entire states or provinces.
1947 division of the North American continent into 86 numbering plan areas (boundaries approximate)[7] |
---|
The original configuration of the North American Numbering Plan assigned eighty-six area codes in October 1947, one each to every numbering plan area.
The territories of the United States, which included Alaska, and Hawaii, did not receive area codes at first, nor did the territories of Canada or Newfoundland and Labrador, which was a British dominion at the time.[7]
Area code | Country/State ID | State, province, or region |
---|---|---|
201 | US:NJ | New Jersey |
202 | US:DC | District of Columbia |
203 | US:CT | Connecticut |
204 | CA:MB | Manitoba |
205 | US:AL | Alabama |
206 | US:WA | Washington |
207 | US:ME | Maine |
208 | US:ID | Idaho |
212 | US:NY | New York (New York City) |
213 | US:CA | California (southern, including Los Angeles) |
214 | US:TX | Texas (northeastern, including Dallas/Fort Worth) |
215 | US:PA | Pennsylvania (southeastern, including Philadelphia) |
216 | US:OH | Ohio (northeastern, including Cleveland) |
217 | US:IL | Illinois (central) |
218 | US:MN | Minnesota (except southeastern part of state) |
301 | US:MD | Maryland |
302 | US:DE | Delaware |
303 | US:CO | Colorado |
304 | US:WV | West Virginia |
305 | US:FL | Florida |
306 | CA:SK | Saskatchewan |
307 | US:WY | Wyoming |
312 | US:IL | Illinois (Chicago metropolitan area) |
313 | US:MI | Michigan (southeast, including Detroit) |
314 | US:MO | Missouri (eastern, including St. Louis) |
315 | US:NY | New York (central upstate, including Syracuse) |
316 | US:KS | Kansas (southern half, including Wichita) |
317 | US:IN | Indiana (northern two-thirds, including Indianapolis) |
319 | US:IA | Iowa (eastern third) |
401 | US:RI | Rhode Island |
402 | US:NE | Nebraska |
403 | CA:AB | Alberta |
404 | US:GA | Georgia |
405 | US:OK | Oklahoma |
406 | US:MT | Montana |
412 | US:PA | Pennsylvania (western, including Pittsburgh) |
413 | US:MA | Massachusetts (western, including Springfield) |
414 | US:WI | Wisconsin (southern and northeastern, including Milwaukee) |
415 | US:CA | California (northern/central, including San Francisco and Oakland) |
416 | CA:ON | Ontario (southern part, including Toronto, below a westward line from Oshawa) |
418 | CA:QC | Quebec (eastern half, including Québec City) |
419 | US:OH | Ohio (northwest, including Toledo) |
501 | US:AR | Arkansas |
502 | US:KY | Kentucky |
503 | US:OR | Oregon |
504 | US:LA | Louisiana |
505 | US:NM | New Mexico |
512 | US:TX | Texas (central and southern, including Austin and San Antonio) |
513 | US:OH | Ohio (southwest, including Cincinnati) |
514 | CA:QC | Quebec (western half, including Montreal) |
515 | US:IA | Iowa (central, including Des Moines) |
517 | US:MI | Michigan (south-central portion of Lower Peninsula, including Lansing) |
518 | US:NY | New York (northeastern, including Albany) |
601 | US:MS | Mississippi |
602 | US:AZ | Arizona |
603 | US:NH | New Hampshire |
604 | CA:BC | British Columbia |
605 | US:SD | South Dakota |
612 | US:MN | Minnesota (southeastern portion, including Minneapolis) |
613 | CA:ON | Ontario (northern part resulting from a westward dividing line from Oshawa on Lake Ontario) |
614 | US:OH | Ohio (southeast, including Columbus) |
616 | US:MI | Michigan (Grand Rapids, Upper Peninsula, western portion of Lower Peninsula) |
617 | US:MA | Massachusetts (eastern, including Boston) |
618 | US:IL | Illinois (southern, including East St. Louis and Carbondale) |
701 | US:ND | North Dakota |
702 | US:NV | Nevada |
703 | US:VA | Virginia |
704 | US:NC | North Carolina |
712 | US:IA | Iowa (western third, including Sioux City) |
713 | US:TX | Texas (southeastern, including Houston) |
715 | US:WI | Wisconsin (northern) |
716 | US:NY | New York (western, including Buffalo and Rochester) |
717 | US:PA | Pennsylvania (eastern half, except for the Delaware and Lehigh valleys) |
801 | US:UT | Utah |
802 | US:VT | Vermont |
803 | US:SC | South Carolina |
812 | US:IN | Indiana (southern) |
814 | US:PA | Pennsylvania (northwestern and central) |
815 | US:IL | Illinois (northern, except Chicago and Quad Cities) |
816 | US:MO | Missouri (northwestern, including Kansas City) |
901 | US:TN | Tennessee |
902 | CA:NS,PE,NB | Nova Scotia, Prince Edward Island, New Brunswick |
913 | US:KS | Kansas (northern half, including Kansas City, Kansas) |
914 | US:NY | New York (southern, including Long Island but excluding New York City) |
915 | US:TX | Texas (western, including El Paso) |
916 | US:CA | California (northern, but not including Sacramento) |
Assignment plan
[edit]States with more than two NPAs | |
---|---|
New York | 212, 315, 518, 716, 914 |
Illinois | 217, 312, 618, 815 |
Ohio | 216, 419, 513, 614 |
Pennsylvania | 215, 412, 717, 814 |
Texas | 214, 512, 713, 915 |
California | 213, 415, 916 |
Iowa | 319, 515, 712 |
Michigan | 313, 517, 616 |
States and provinces with two NPAs | |
Indiana, Kansas, Massachusetts,
Minnesota, Missouri, Wisconsin, Ontario, Quebec |
The number of central offices that could be effectively installed with a numbering plan with two letters and one digit for the central office code was expected to be approximately five hundred, because acceptable names for central offices had to be selected carefully to avoid miscommunication.[9] States or provinces that required this many offices had to be divided into multiple smaller areas. Next to size, another important aspect was the existing infrastructure for call routing, which had developed during preceding decades independently of state or municipal boundaries. Since traffic between numbering plan areas would require special Class-4 toll switching systems, planning the divisions avoided cutting busy toll traffic routes, so that most toll traffic remained within an area, and outgoing traffic from one area would not be tributary to toll offices in an adjacent area.[11][9] However, it was recognized already in 1930 that too little granularity in the allocation pattern introduced expensive traffic back-haul requirements, conceivably resulting in congestion of the routes to the centers.[2]
Consideration of several assignment patterns resulted in the configuration that was publicized as a map in October 1947.[7] The three-digit codes were assigned to numbering plan areas in seemingly random manner, avoiding consecutive, nearly-consecutive, or just very similar codes in neighboring numbering plan areas to avoid customer confusion,[12] even when located in the same jurisdiction. This criterion was not always achieved, however. A more geography-based enumeration method had been examined earlier, but was discarded. Thus, it would not have been possible to locate the approximate geographic location of a numbering plan area by its code alone. The plan divided New York into five areas, the most of any state. Illinois, Ohio, Pennsylvania, and Texas were assigned four area codes each, and California, Iowa, and Michigan received three. Eight states and provinces were divided into two NPAs.
The pattern of this assignment of area codes is shown in the following tabulation. This method of arrangement, which is known to have been in use at Bell Laboratories,[13] shows clearly that area codes were assigned not entirely in random order, but by filling the table in diagonal manner from the top left corner, containing the low-numbered area codes, toward the center and lower right corner. Such a pattern suggests that the designers intended to maintain the same degree of randomness in digits for the remaining, yet unassigned codes. The first area code (201) was given to the entire state of New Jersey, the state with the greatest population density in the nation. Despite its density, the state was not subdivided until about a decade later. In fact, in the group of single-NPA states, having the middle digit 0, all of the low-number codes were assigned to the mid-Atlantic states around New Jersey, i.e. the District of Columbia, Connecticut, Maryland, Delaware, and Rhode Island, all states in the top of the list of states with the greatest population densities.[14]
Because telephones of this era, e.g. the Western Electric 302 desk rotary phone or the M3 354 wall telephone, were designed to send pulses or clicks to the central office's switching station, smaller digits were quicker to dial. This makes the fastest-dialing area code 212 (5 total clicks), followed by 312 and 213 (6 clicks). The area code 605 is much slower than these, at 21 clicks. Many large US cities generally had fast-dialing area codes with the middle digit 1. Touch-tone dialing, introduced later, eliminated the wait.
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Notes: † Special dialing codes (not permitted as area codes)–Area codes could not begin with N=0 or 1, or end in 0 |
In this table, the assignments of the nine area codes to the Canadian provinces are highlighted by a blue background. The red fields are the NPAs that hosted the Regional Centers for toll-switching established in the General Toll Switching Plan of 1929:[2] New York City (212), Los Angeles (213), Dallas (214), Chicago (312), St. Louis (314), and San Francisco (415) in the multi-NPA states, and in Denver (303) and Atlanta (404) in states with just a single area code each. These NPAs are clustered in the upper left corner, especially in the multiple-NPA table, but area codes 303 and 404 also fit neatly into the corresponding white positions of the N1X table (not Regional Centers), so that the Regional Center formed an almost closed block when ignoring the middle digit.
These assignments of these Regional Centers was complemented by assignments to the toll offices (in orange fields) in Detroit (313), serving the busy toll route to Toronto,[15] and in Philadelphia (215), which had been chosen for the first cut-over into commercial service of a No. 4 Crossbar toll switch in 1943 for regional toll service.[16]
The codes of the forms N00, N10, and N11, where N is 2 through 9, were not available for assignment as area codes at the time, but were reserved as special codes,[9] leaving a total of 136 possible combinations. The series N00 was used later for non-geographic numbers, starting with intrastate toll-free 800 numbers for Inward Wide Area Telephone Service (WATS) in 1965.[17] N10 numbers became teletypewriter exchanges,[18] and N11 were used for special services, such as information and emergency services.
Implementation and expansion
[edit]For several years, area codes could be used only for Operator Toll Dialing by long-distance operators on routes between toll offices equipped with trunk code translation equipment. This absent, operators still had to rely on route operators and office-specific trunk codes, or employ the previous method of ringdown forwarding between intermediate operators.[7] For entering the destination codes and telephone numbers into newly designed machine-switching equipment, long-distance operators did not use the slow rotary dials, but a ten-button key set, operating at least twice as fast, which transmitted multi-frequency (MF) tone pulses over regular voice channels to the remote switching stations.[19][20] Such channels were incapable of transmitting the direct-current pulses of a rotary dial beyond a single link. All existing toll switching offices, many still using direct-control (step-by-step) methods, had to be supplemented with components to permit MF signaling and automatic route selection.
In December 1948, AT&T advanced the new long-distance technology with the cutover of new crossbar switching systems for toll-dialing in New York and Chicago,[21] which added new technology to the No. 4 Crossbar Switching System, first installed in Philadelphia in 1943. This enabled operators to make calls directly to distant telephones without additional operators en route to some three hundred cities, and resulted in the handling of about ten percent of all Bell System long-distance calling by Operator Toll Dialing.[19] On average, it took about two minutes for any long-distance call to be completed to its destination. As foreseen and stated in 1949, the target goal for call completion, after full implementation of the system across the nation, was one minute.
As new switching systems came online and design and manufacture of other routing infrastructure proceeded, the implementation of the new numbering plan advanced and several numbering plan areas were redrawn or added during subsequent years. In 1948, northern Indiana received an extra area code (219) for its Chicago suburbs by dividing area code 317.[22] In 1950, southwest Missouri, with a new toll-center in Joplin, received area code 417, a change that provided more central offices in Kansas City. In 1951, the number of area codes grew to ninety: the State of New York gained area code 516 on Long Island, and Southern California received area code 714, to reduce the numbering plan area of Los Angeles.[23]
By 1951, a new Class-5 switching system, the No.5 Crossbar, had proven successful in Media, Pennsylvania, and automatic message accounting (AMA) became available for billing telephone calls. The switching system was capable of handling the dialing of as many as eleven digits by subscribers.[24] In Englewood, New Jersey, such a system was linked to a toll-class switch with the first commercial transistor circuitry that enabled the system to automatically translate area codes into toll trunk codes.[25] On November 10, 1951, the system commenced a customer trial of direct distance dialing (DDD) from this single location in the country.
From the customer dialing experience in the Englewood DDD trials, Bell Laboratories engineers gained the confidence to predict that customers would use the new numbering plan with a reasonable degree of convenience and accuracy.[26] After the success of these trials,[23][27] expansion of the numbering plan accelerated with new crossbar systems and four new area codes in 1953, and seven in 1954. By the end of the decade thirty-one new area codes had been created in addition to the initial allotment of 1947.[28] to satisfy the post-war surge in demand for telephone service.
While the first customer-dialed call using an area code was made in 1951, it took nearly fifteen years after the 1947 announcement of the new numbering plan that direct distance dialing was common in most cities. By then, some of the initial criteria for assignment, such as the 0/1 rule for single/multiple NPA assignments in a given state had to be abandoned by new requirements from population shifts and growth of communication services. In 1960, AT&T engineers, estimating that the capacity of the numbering plan would be exhausted by 1975,[28] prepared for the next major advance in the evolution of the network by eliminating central office names, and introducing all-number calling (ANC). ANC, once supplemented by interchangeable central office codes during the 1970s, increased the number of central office prefixes possible in each numbering plan area from 540 to an eventual maximum of 792.
See also
[edit]References
[edit]- ^ Hill, A.W. (1926-09-11). "Dawn of Unified Telephone Service". Telephony. 99 (11): 29.
The old, and in the main, disastrous cutthroat methods formerly existing between the Bell and Independent companies are relegated to the past. The public has come to see the situation in its true light. and more and more growing is the demand for a universal telephone system, regardless of who the owner of the particular unit serving their section may be.
- ^ a b c BSTJ 9: 3. July 1930: A General Switching Plan for Telephone Toll Service. (Osbourne, H.S.). July 1930.
- ^ Hosford, Howard L. (Winter 1943). "A Dial Switching System for Toll Calls". Bell Telephone Magazine. 22 (4): 230. Retrieved 2022-04-23.
- ^ Pilliod, James J.; Ryan, Harold L. (Summer 1945). "Operator Toll Dialing—A New Long Distance Method". Bell Telephone Magazine. 24 (2): 101–115. Retrieved 2022-01-02.
- ^ Annual Report for the Year 1945. American Telephone and Telegraph Company. 1946-02-15. p. 15.
- ^ Norris, F.E. (Chairman); USITA (1946-01-12). "Nationwide Operator Toll Dialing" (PDF). Telephony. 130 (2): 13.
- ^ a b c d e f g h Mabbs, Ralph (Winter 1947–1948). "Nation-Wide Operator Toll Dialing—the Coming Way". Bell Telephone Magazine. 26 (4): 181. Retrieved 2022-04-23.
- ^ "Bell System distributes Notes on Nationwide Dialing". Telephony. 148 (6): 55. 1955-02-05.
- ^ a b c d e f 'Notes on Nationwide Dialing (PDF) (Report). Department of Operation and Engineering, AT&T. 1955. Archived (PDF) from the original on 2014-10-14. Retrieved 2022-04-28 – via Exploding the Phone.
- ^ Shipley, F. F. (October 1945). "Nation-Wide Dialing" (PDF). Bell Laboratories Record (10): 368–372. Retrieved 2022-10-13.
- ^ W.H. Nunn, Nationwide Numbering Plan, Bell System Technical Journal 31(5), 851 (1952)
- ^ Erickson, Andrew (March 2021). "New In Town". American University Magazine. Retrieved January 7, 2022.
(NANPA] relies on a tried-and-true methodology that considers factors like customer confusion.
- ^ Keevers, R. J. (1975-12-12). "North American Numbering Plan–The First Thirty Years". Bell Laboratories Memorandum No. 40978.
- ^ "Historical Population Density Data (1910–2020)". United States Census Bureau. 2021-04-26. Retrieved 2022-01-12.
- ^ H. S. Osborne, A General Switching Plan for Telephone Toll Service, Bell System Technical Journal Vol 9 (3), July 1930, p.431
- ^ Clark, A. B.; Osborne, H. S. (1952). "Automatic Switching for Nationwide Telephone Service". Bell System Technical Journal. 3 (5): 823. doi:10.1002/j.1538-7305.1952.tb01410.x. S2CID 51639224.
- ^ AT&T, Events in Telephone History, AT&T Public Relations, New York (1974)
- ^ AT&T, Notes on the Network (1968), Section 9
- ^ a b "Nation-Wide Toll Dialing Makes Its Bow" (PDF). Bell Laboratories Record. 27 (2): 71–72. February 1949. Retrieved 2022-01-20.
- ^ Moody, D. L. (December 1945). "Multi-Frequency Pulsing" (PDF). Bell Laboratories Record. 23 (12): 466–470. Retrieved 2022-01-20.
- ^ Guengerich, E. J. (Winter 1948). "Toll Dialing by Operators Reaches Some 300 Places". Bell Telephone Magazine. 27 (4): 228–237. Retrieved 2022-01-20.
- ^ "Nation-Wide System for Toll-Line Dialing" (PDF). Bell Laboratories Record. 27 (1): 29. January 1949. Retrieved 2022-01-20.
- ^ a b Baker, Ernest W. (Winter 1951). "Toll Dialing Is Expanding Throughout the Nation". Bell Telephone Magazine. 30 (4): 253. Retrieved 2022-01-20.
- ^ Korn, F.A.; Ferguson, James G. (1950). "Number 5 Crossbar Dial Telephone Switching System". AIEE Transactions. 69 (1): 244–254. doi:10.1109/T-AIEE.1950.5060147. S2CID 51637587.
The Number 5 Crossbar System ... can be used for as few as four digits in a subscriber number, or as many as 11 digits may be used to code the called subscriber completely. (abstract)
- ^ P. Mallery, Transistors and Their Circuits in the 4A Toll Crossbar Switching System, AIEE Transactions, September 1953, p.388
- ^ Nunn, W.H. (1952). "Nationwide Numbering Plan". Bell System Technical Journal. 31 (5): 959. doi:10.1002/j.1538-7305.1952.tb01412.x. Retrieved 2022-01-20.
- ^ AT&T Corporation. "1951: First Direct-Dial Transcontinental Telephone Call". Archived from the original on 2007-01-07. Retrieved 2020-08-25.
- ^ a b Sinks, William A. (Winter 1959). "New Numbers for Tomorrow's Telephones". Bell Telephone Magazine. 38: 6–15.