The prototype for the exchange which the
GPO called TXE2 was a system called Pentex (the Plessey trademark for all non-GPO sales), which, starting in 1963, was developed by
Ericsson Telephones, as part of Plessey. The first field trial of Pentex started in the Peterborough Telephone Area in 1965. There was another trial site at Leamington. The system was designed to serve 200–1,200 customers and about 240
Erlang units. It was therefore mainly used to replace the larger rural
Strowger exchanges – usually UAX13s. The first TXE2 was installed at
Ambergate, some 20 miles from the Plessey factory at
Beeston, and opened on 15 December 1966. Although the system had been developed by Plessey, the GPO had insisted on competitive tendering for the TXE2 exchanges. Production contracts were awarded simultaneously to Plessey, STC, and GEC. Some 2–3,000 TXE2s went into service with the GPO, the last one being withdrawn from service on 23 June 1995. The Pentex system, which evolved beyond TXE2, was exported to over 30 countries and was largely responsible for Plessey winning the
Queen's Award for Exports in 1978.
Exchange description Because of their
common control design, isolation (inability of the exchange to set up calls) of the entire exchange was always a possibility and very occasionally happened. This potential weakness had been at least partially recognised in the design of the exchange type, so the most critical common control units were split into three sections and each section was duplicated into an A-side and a B-side. In the event of the equipment detecting a serious fault in one of the side-conscious units, all the units in that section were locked onto the side which was giving good service and a prompt alarm was sent to a staffed centre to indicate that the exchange needed urgent attention. In normal service, the exchange automatically changed all three sections from one side to the other every eight minutes. If Call Control detected eight failures to set up calls within that eight minutes, then it force-changed all the side-conscious units onto the other side, locked that side in service and raised a prompt alarm. In periods of very low traffic, there would typically be fewer than eight call set-up attempts on the exchange in eight minutes and this would have prevented the above security system from working. The exchange was therefore provided with an automatic Test Call Unit, which originated a test call every 30 seconds. As well as thus enabling Call Control to detect eight failures in less than eight minutes (if all call-attempts were failing), the Test Call would raise its own prompt alarm if it detected 31 sequential call-attempt failures, indicating that neither security side of the exchange was able to connect calls. . The red lamps show that all three sections are alarmed. The 8-minute changeover will have been suspended and the white lamps show that all three security sections are locked on to side B. As a further security measure, if the first attempt to set up a path to a register failed, so that, on an outgoing call, the customer did not get dial-tone, the exchange recognised the failure, stored the details of the equipment in use on the failed call and automatically made a second attempt, using different equipment. This happened so quickly (about 50 milliseconds) that, if the second attempt was successful, the customer would not have been aware of the failed first attempt to get dial-tone. Unlike the preceding rural Strowger exchanges (UAX 13s and smaller) the TXE2s were equipped with an
uninterruptible power supply with auto-starting diesel generators. UAX13 which it replaced. As a maintenance aid, the exchange was equipped with a Maintenance Data Recorder (MDR). This had a rather primitive printer, which displayed the identities of equipment in use at the time that the exchange had detected a call failure. For example, in the event of a successful repeat attempt to provide dial-tone, the MDR would print. If the repeat attempt failed, then the MDR would print twice in quick succession, giving details of the equipment in use on both the failed paths. The prints were not easy to read. All that emerged were short burn marks on the special paper in up to 45 different places in each of two rows. It was necessary to hold a plastic graticule (see picture below right, under that of an MDR) over the paper to find out what the presence of each burn mark indicated. If more than eight call failures were detected in less than 8 minutes, then the critical common control units would be forced to change from the side in service (A or B) to the other side, the automatic 8-minute changeover would be suspended and a prompt alarm would be sent out. . It was feared that this type of connector would cause problems after a relatively low number of removal/re-insertion operations, but in practice, they proved to be more than adequately robust. In TXE2s, a call which terminated within the same exchange went through seven switching stages, whereas a call going out to another exchange went through just three switching stages. The switches were designated as A, B, C, and D (the paths were A-B-C for outgoing, D-C-B-A for incoming, and A-B-C-D-C-B-A for internal). The common control equipment consisted of B- and C-switch selectors, supervisory selectors (a supervisory relay set stayed in-circuit throughout each call), Register Selectors, Registers, and Call Control. The most characteristic feature of the exchange's central control unit design was that calls were processed serially. Consequently, call set-up had to be fast. In particular, Call Control had to become free in less than the time of the inter-digital pause on calls incoming to the exchange. This time could be as low as 60 milliseconds. As the TXE2 call-set-up time was some 50 milliseconds, this design requirement was just met, but even so, the overall capacity of the system was determined by the probability of an incoming call being delayed too long in its initial connection to a register. The
grade of service in a TXE2 was dependent on the number of customers in an A-switch group, with access to just 25 A-B trunks. The normal standard on the earlier exchanges was 125 customers per A-switch group. If the A-switch group contained many busy
PBX lines, then the number of customers might be reduced to 75. The earlier (Mark I and Mark II – the differences being slight) exchanges could handle up to 2,000 customers. Later on, Mark III TXE2s were able to handle up to 4,000 customers and on these exchanges, where the average calling rate was sufficiently low, up to 250 customers would be in an A-switch group, still with access to just 25 A-B trunks. The choice of the main type of memory used in the TXE2 (and the TXE4) was particularly characteristic of the general design philosophy, that the components used had to be of a technology that had been tested over many years. The choice thus went to the
Dimond ring type of memory, named after T. L. Dimond of Bell Laboratories, who invented in 1945. They were large-diameter magnetic ferrite toroidal rings with solenoid windings, through which are threaded writing and reading wires. These racks gave the ability to convert a subscriber's directory number into an equipment location identity. This was a considerable innovation in British exchanges since in Strowger exchanges the directory and equipment numbers had to be the same. The switching in TXE2s was carried out by
reed relays and a typical TXE2 contained about 100,000 reeds. The reeds were fast in operation, with a life expectancy of more than 10 million operations. The glass capsules were about an inch (25 mm) in length and about an eighth of an inch (3 mm) in diameter. Four reeds were generally present inside each relay coil, two for the speech-path, one for holding the path and one for metering. Switching with these reeds held out the prospect of much greater reliability compared with the Strowger system, where switching was carried out by base metal wipers moving through banks of metal contacts. The Strowger switches required routines to be carried out on them to clean the banks: they also required oiling and occasional adjustment. Reed relays required none of this. However, in practice, and particularly in the early years of the system's service, the performance of the reeds proved to be worse than had been expected.
Maintenance and reliability The TXE2-specific equipment was different in the TXE2s manufactured by Plessey, STC, and GEC, so that spare equipment had to be held for each type of manufacturer. Importantly, each manufacturer made their own reed inserts (reed were manufactured for GEC by their subsidiary, the Mazda Osram Valve Company) and their performance differed significantly in the first years of production. All the TXE2-specific equipment was mounted on slide-in units, mainly single-width, but some double-width. There was a structured holding of maintenance spare units. For those which were likely to be needed frequently or urgently in every exchange, such as a Subscribers Line Unit, a spare unit was held in every exchange. For those units for which a spare was likely to be needed less frequently or urgently, the spares were held at an Area centre serving perhaps 6–10 TXE2s of the same manufacture. Finally for those units for which a spare was likely to be needed seldom, the spare units were held at one centre per Region - there being ten Regions in the UK. In the early (around 1969) Plessey exchanges, a significantly high proportion of the reed-inserts were contaminated with a high-resistance film and were prone to giving an intermittently high-resistance contact. If this occurred in one of the common-control areas of the exchange, it could give rise to the exchange becoming isolated (being unable to set up any calls) for as much as several hours. These faults were very difficult to locate, and in the end, the problems were only resolved by a fairly substantial re-reeding programme carried out on the common-control units of the early Plessey exchanges. The STC reeds proved to be more reliable, but, if they failed, they tended to stick or short-circuit. This was also a cause of isolations early on, but a simple modification restricted the most serious type of failure to a small part of the exchange. The GEC/MOV reeds proved to be the most reliable of all. Once the teething troubles had been largely dealt with, which was not until about 1974, the TXE2s realised more of their expected benefits and it was eventually not uncommon for one Technical Officer to maintain the operation of three of these exchanges, serving perhaps some 5,000–6,000 customers in total.
Preservation In the summer of 2005 a demonstration rack of TXE2 equipment was transferred to the
Connected Earth collection at
Milton Keynes Museum. There is a working MXE2 (mobile variant) at
Avoncroft Museum. It can be used to make calls within the museum. Many of the MXE2s ended up in Northern Ireland. Only one of these ever had to be used 'in anger'. This was at
Castlewellan about 1990, when the exchange was blown up by terrorists. The typical set-up time for an MXE2 was about six weeks, but at Castlewellan, full telephone service was restored using an MXE2 (and the additional use of a mobile transmission unit designed by Northern Ireland staff) within one week of the bombing. It did, however, take a lot of subsequent work by the switch maintenance Technical Officers to get the exchange up to an acceptable standard of service, as it had been standing idle for several years. ==TXE3==