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Mobile Telephone
Analog Mobile Systems 
(1st Generation)

by: Lawrence Harte

Analog cellular is an industry term given to first generation (1G) cellular systems that transmit voice information using a form of analog modulation (e.g. FM). Analog cellular systems may have digital control channels. Analog cellular systems primarily provide voice and low-speed data communication services over a wide geographic area.


Analog cellular systems use very narrow radio channel (small amount of bandwidth) that varies from 10 kHz to 30 kHz. Analog systems usually send control information in digital (data) form. The data signaling rates determine how fast messages can be sent on control channels. The RF power level of mobile telephones and how the power level is controlled ordinarily determines how far away the mobile telephone can operate from the base station (radio tower).


Regardless of the size and type of radio channels, all cellular and PCS systems allow for full duplex operation. Full duplex operation is the ability to have simultaneous communications between the caller and the called person. This means a mobile telephone must be capable of simultaneously transmitting and receiving to the radio tower. The radio channel from the mobile telephone to the radio tower is called the uplink and the radio transmission channel from the base station to the mobile telephone is called the downlink. The uplink and downlink radio channels are normally separated by 45 MHz to 80 MHz.


In early mobile radio systems, a mobile telephone scanned the limited number of available channels until it found an unused one, which allowed it to initiate a call. Because the analog cellular systems in use today have hundreds of radio channels, a mobile telephone cannot scan them all in a reasonable amount of time. To quickly direct a mobile telephone to an available channel, some of the available radio channels are dedicated as control channels. Most cellular systems use two types of radio channels, control channels and voice channels. Control channels carry only digital messages and signals, which allow the mobile telephone to retrieve system control information and compete for access.

This article is Part 5 of a 9 Part Series
Mobile Telephone List

Month
Mobile Technologies Oct 06
Mobile Devices Nov 06
Mobile Systems Dec 06
Mobile Systems Operation Jan 07
Analog Systems Feb 07
Digital Cellular Systems Mar 07
Packet Digital Cellular Systems Apr 07
Wideband Digital Cellular May 07
Mobile Services Jun 07

Control channels only carry control information such as paging (alert) and channel assignment messages. Voice channels are primarily used to transfer voice information. However, voice channels must also be capable of sending and receiving some digital control messages to allow for necessary frequency and power changes during a call. 


Current analog systems serve only one subscriber at a time on a radio channel so the number of radio channels available influence system capacity. However, a typical subscriber uses the system for only a few minutes a day, on a daily basis, and many subscribers share a single channel. As a rule, 20 - 32 subscribers share each radio channel [ ], depending upon the average talk time per hour per subscriber. Generally, a cell with 50 channels can support 1000 - 1600 subscribers.


The basic operation of an analog cellular system involves initiation of the phone when it is powered on, listening for paging messages (idle), attempting access when required and conversation (or data) mode. 


When a mobile telephone is first powered on, it initializes itself by searching (scanning) a predetermined set of control channels and then tuning to the strongest one. During the initialization mode, it listens to messages on the control channel to retrieve system identification and setup information.


After initialization, the mobile telephone enters the idle mode and waits to be paged for an incoming call and senses if the user has initiated (dialed) a call (access). When a call begins to be received or initiated, the mobile telephone enters system access mode to try to access the system via a control channel. When it gains access, the control channel sends an initial voice channel designation message indicating an open voice channel. The mobile telephone then tunes to the designated voice channel and enters the conversation mode. As the mobile telephone operates on a voice channel, the system uses Frequency Modulation (FM) similar to commercial broadcast FM radio. To send control messages on the voice channel, the voice information is either 

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replaced by a short burst (blank and burst) message or in some systems, control messages can be sent along with the audio signal.


A mobile telephone's attempt to obtain service from a cellular system is referred to as access. Mobile telephones compete on the control channel to obtain access from a cellular system. Access is attempted when a command is received by the mobile telephone indicating the system needs to service that mobile telephone (such as a paging message indicating a call to be received) or as a result of a request from the user to place a call. The mobile telephone gains access by monitoring the busy/idle status of the control channel both before and during transmission of the access attempt message. If the channel is available, the mobile station begins to transmit and the base station simultaneously monitors the channel's busy status. Transmissions must begin within a prescribed time limit after the mobile station finds that the control channel access is free, or the access attempt is stopped on the assumption that another mobile telephone has possibly gained the attention of the base station control channel receiver. 


If the access attempt succeeds, the system sends out a channel assignment message commanding the mobile telephone to tune to a cellular voice channel. When a subscriber dials the mobile telephone to initiate a call, it is called "origination". A call origination access attempt message is sent to the cellular system that contains the dialed digits, identity information along with other information. If the system allows service, the system will assign a voice channel by sending a voice channel designator message, if a voice channel is available. If the access attempt fails, the mobile telephone waits a random amount of time before trying again. The mobile station uses a random number generating (an internal algorithm) to determine the random time to wait. The design of the system minimizes the chance of repeated collisions between different mobile stations, which are both trying to access the control channel since each one waits a different random time interval before trying again if they have already collided on their first, simultaneous attempt.


To receive calls, a mobile telephone is notified of an incoming call by a process called paging. A page is a control channel message that contains the telephone's Mobile Identification Number (MIN) or telephone number of the desired mobile phone. When the telephone determines it has been paged, it responds automatically with a system access message that indicates its access attempt is the result of a page message and the mobile telephone begins to ring to alert the customer of an incoming telephone call. When the customer answers the call (user presses "SEND" or "TALK"), the mobile telephone transmits a service request to the system to answer the call. It does this by sending the telephone number and an electronic serial number to provide the users identity. 


After a mobile telephone has been commanded to tune to a radio voice channel, it sends mostly voice or other customer information. Periodically, control messages may be sent between the base station and the mobile telephone. Control messages may command the mobile 

telephone to adjust its power level, change frequencies, or request a special service (such as three way calling).


To conserve battery life, a mobile phone may be permitted by the base station to only transmit when it senses the mobile telephone's user is talking. When there is silence, the mobile telephone may stop transmitting for brief periods of time (several seconds). When the mobile telephone user begins to talk again, the transmitter is turned on again. This is called discontinuous transmission.


Figure 1.14 shows a basic analog cellular system. This diagram shows that there are two types of radio channels; control channels and voice channels. Control channels typically use frequency shift keying (FSK) to send control messages (data) between the mobile phone and the base station. Voice channels typically use FM modulation with brief bursts of digital information to allow control messages (such as handoff) during conversation. Base stations typically have two antennas for receiving and one for transmitting. Dual receiver antennas increases the ability to receive the radio signal from mobile telephones which typically have a much lower transmitter power level than the transmitters in the base station. Base stations are connected to a mobile switching center (MSC) typically by a high speed telephone line or microwave radio system. This interconnection must allow both voice and control information to be exchanged between the switching system and the base station. The MSC is connected to the telephone network to allow mobile telephones to be connected to standard landline telephones.


There are many types of analog and digital cellular systems in use throughout the world. Analog systems include AMPS, TACS, JTACS, NMT, MCS and CNET. 


Advanced Mobile Phone Service (AMPS)


Advanced mobile phone service (AMPS) is an analog cellular communications system that uses frequency-division multiple Access (FDMA) for control and frequency division duplex (FDD) for two transmission. The AMPS radio channel types include 30 kHz FSK control channels and 30 kHz voice channels and it operates in the 825 MHz to 890 MHz frequency range.


In 1974, 40 MHz of spectrum was allocated in the United States for cellular service [ ] that provided only 666 channels. In 1986, an additional 10 MHz of spectrum was added to facilitate expansion [ ] of the system to 832 channels. 


The frequency bands for the AMPS system are 824 MHz to 849 MHz (uplink) and 869 MHz to 894 MHz (downlink). Of the 832 channels, AMPS systems are divided into A and B bands to allow for 2 different service providers. There are two types of radio channels in an AMPS system; dedicated control channels and voice channels. On each system (A or B), mobile telephones scan and tune to one of 21 dedicated control channels to listen for pages and compete for access 

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Figure 1.14., Analog Cellular System (1st Generation)
to the system. The control channel continuously sends system identification information and access control information. Although the control channel data rate is 10 kbps, messages are repeated 5 times, which reduces the effective channel rate to below 2 kbps.

 This allows a control channel to send 10 to 20 pages per second. 
The AMPS cellular system is a frequency duplex with its channels separated by 45 MHz. The control channel and voice channel signals are transferred at 10 kbps. AMPS cellular phones have three classes of maximum output power. A class 1 mobile telephone has a maximum power output of 6 dBW (4 Watts), class 2 has a maximum output power of 2 dBW (1.6 Watts), and the class 3 units are capable of delivering only -2 dBW (0.6 Watts). The output power can be adjusted in 4 dB steps and has a minimum output power of -22 dBW (approximately 6 milliwatts).


Total Access Communication System (TACS)


Total access communications system is an analog mobile telephone system that is an enhanced version of AMPS (analog cellular). It was developed and deployed in the United Kingdom and it primarily operates on the 900 MHz frequency range. In the late 1990s, TACS systems began converting to GSM systems.

The Total Access Communication System (TACS) is very similar to the US EIA-553 AMPS system. Its primary differences include changes to the radio channel frequencies, radio channel bandwidths and data signaling rates. The TACS was introduced to the U.K. in 1985. After its introduction in the UK in 1985, over 25 countries offered TACS service. The introduction of the TACS system was very successful and the system was expanded to add more channels through what is called Extended TACS (ETACS).


The TACS system was deployed in 25kHz radio channels compared to the 30kHz channels used in AMPS. This narrower radio bandwidth reduced the data speed of the signaling channel.


The frequency ranges of most TACS systems are 890 MHz to 915 MHz for the uplink and 935 MHz to 960 MHz for the downlink. The TACS system was initially allocated at 25 MHz although 10 MHz of the 25 MHz was reserved for future pan-European systems in the UK. An additional 16 MHz of radio channel bandwidth was added to allow for Extended TACS (ETACS). The ETACS system is a frequency duplex system with its channels separated by 45 MHz. 


The control channel and voice channel signals are transferred at 8 kbps. There are 4 power classes for ETACS mobile telephones. Class 1 mobile telephones have a maximum output of 10 Watts, class 2 has 4 Watts, class 3 has 1.6 Watts, and class 4 has 0.6 Watts. Similar to AMPS, mobile telephones can be adjusted in 4 dB steps and have a minimum transmit power level of approximately 6 milliwatts.

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The TACS system has also been modified for use in Japan. This Japanese version is called JTACS. The only significant changes were the frequency bands and number of channels. The TACS system has also been modified to create the Narrowband TACS (NTACS) system. NTACS reduced the radio channel bandwidth from 25 kHz to 12.5 kHz and changed the in-band 8 kbps signaling on the voice channel to 100 bps sub-band digital signaling.


Nordic Mobile Telephone (NMT)


Nordic mobile telephone is a mobile cellular telephone system that was introduced to Europe in 1981. The NMT system has been deployed on two frequency bands; 450 MHz and 900 MHz. These systems use FM (analog) radio modulation. In the 1990s, NMTS systems were converted to the GSM (digital) system.


The NMT 450 system is a low capacity system and NMT 900 that is a high capacity system. The Nordic mobile telephone (NMT) system was developed by the telecommunications administrations of Sweden, Norway, Finland, and Denmark to create a compatible mobile telephone system in the Nordic countries [ ]. The first commercial NMT 450 cellular system was available at the end of 1981. Due to the rapid success of the initial NMT 450 system and limited capacity of the original system design, the NMT 900-system version was introduced in 1986. 


The NMT 450 system uses a lower frequency (450 MHz) and higher maximum transmitter power level. This allows a larger cell site coverage areas while the NMT 900 system uses a higher frequency (approximately the same 900 MHz band used for TACS and GSM) and a lower maximum transmitter power, which increases system capacity. NMT 450 and NMT 900 systems can co-exist which permits them to use the same switching center [ ]. This allowed some NMT service providers to start offering service with an NMT 450 system and progress up to a NMT 900 system when the need arises.

Some operations of the NMT systems are very different from most other cellular systems. When NMT mobile telephones access the cellular system, they can either find an unused voice channel and negotiate access directly or begin conversation without the assistance of a dedicated control channel. Because scanning for free voice channels can be very time consuming, the NMT 900 system does allow for the use of a dedicated control channel that is called the calling channel. The NMT 900 system also allows discontinuous reception, which increases the standby time of the portable phones.


The NMT 450 system is frequency duplex with 180 channels (except Finland which only has 160 channels) [ ]. The radio channel bandwidth is 25 kHz and the frequency duplex spacing is 10 MHz. The NMT 900 system has 999 channels or 1999 interleaved channels. 


Signaling on the NMT systems is performed at 1200 bps on the control (calling) channel (NMT 900) and voice channel. Because of the slow signaling rate and robust error detection/correction capability, no repeated messages are necessary. 


NMT 450 base stations can transmit up to 50W. This high power combined with the lower 450 MHz frequency allows cell site size of up to approximately 40 km radius. NMT 900 base stations are limited to a maximum of 25W that allows a maximum cell size radius of up to approximately 20 km [ ].


There are three power levels (high, medium, and low) for NMT mobile phones and two power levels (high and low) for portables. NMT 450 mobile telephone power levels are: High 15W, Medium 1.5W, and Low 0.15W, NMT 450 portable telephones; High 1.0W, Low 0.1W. NMT 900 mobile telephones: High 6.0W, Medium 1.0W, Low 0.1W and NMT 900 portable telephones: High 1.0W, Low 0.1W.


The NMT system is unique as it included various types of anti-fraud protection. NMT mobile telephones hold a three-digit password that is stored in the telephone and cellular switching center and is unknown to the customer. This password is sent to the cellular system during system access along with the mobile telephone number. The NMT system has also added a Subscriber Identity Security (SIS) system that provides additional anti-fraud protection. Not all NMT telephones have SIS capability.

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Narrowband AMPS (NAMPS)


Narrowband AMPS is a cellular system that allows the use of either 30 kHz or 10 kHz FM modulated (analog) channels. The NAMPS system was developed to increase the serving system capacity by allowing each base station to contain more channels (transceivers). NAMPS adds sub-band signaling operation to the signaling control channels used in the AMPS system.


NAMPS was commercially introduced by Motorola in late 1991 and was deployed worldwide. Like the existing AMPS technology, NAMPS uses analog FM radio for voice transmissions. The distinguishing feature of NAMPS is its use of a "narrow" 10 kHz bandwidth for radio channels, a third of the size of AMPS channels. Because more of these narrower radio channels can be installed in each cell site, NAMPS systems can serve more subscribers than AMPS systems without adding new cell sites. NAMPS also shifts some control commands to the sub-audible frequency range to facilitate simultaneous voice and data transmissions.


In 1991, the first NAMPS standard, named IS-88, evolved from the US AMPS specification (EIA-553). The IS-88 standard identified parameters needed to begin designing NAMPS radios, such as radio channel bandwidth, type of modulation, and message format. During development, the NAMPS specification benefited from the narrowband JTACS radio system specifications. During the following years, advanced features such as ESN authentication, caller ID, and short messaging were added to the NAMPS specification. 

Japanese Mobile Cellular System (MCS)

Japan launched the world's first commercial cellular system in 1979. Because this system had achieved great success, several different types of cellular systems have evolved in Japan. These include the MCS-L1, MCS-L2, JTACS and NTACS systems.

The MCS-L1 was the first cellular system in Japan, which was developed and operated by NTT. The system operates in the 800 MHz band. The channel bandwidth is 25 kHz and the signaling is at 300 bps. The control channels are simulcast from all base stations in the local area. This limits the maximum capacity of the MCS-L1 system. 


Because the MCS-L1 system could only serve a limited number of customers, the MCS-L2 system was developed. It uses the same frequency bands as the MCS-L1 system. The radio channel bandwidth was reduced from 25 kHz to 12.5 kHz with 6.25 kHz interleaving. This gives the MCS-L2 system 2,400 channels. The control channels transfer information at 2,400 bps and the voice channels can use either in-band (blank and burst) signaling at 2,400 bps or sub-band digital audio 

signaling at 150 bps. MCS-L2 mobile telephones have diversity reception (similar to diversity reception used in base stations). While this increases the cost and size of the mobile telephones, it also increases the performance and range of the cellular system.


CNET

CNET is an analog cellular system that is used in Germany, Portugal, and South Africa [ ]. The first CNET system started operation in Germany in 1985. The primary objective of the CNET system was to bridge the gap of cellular systems in Germany until the digital European system could be introduced [ ]. 


The CNET system operates at 450 MHz with 4.44 MHz transmit and receive bands. The frequency bands are 461.3 to 465.74 MHz and 451.3 to 455.74 MHz. The primary channel bandwidth is 20 kHz with 10 kHz channel interleaving. 


The CNET system continuously exchanges digital information between the mobile telephone and the base station. Every 12.5 msec, 4 bits of information are sent during compressed speech periods [ ]. CNET mobile telephones also use an Identification Card (IC), which slides into the telephone to identify the customer. This allows customers to use any compatible CNET telephone.


MATS-E


The MATS-E system is used in France and Kuwait [ ]. The MATS-E system combines many of the features used in different cellular systems. MATS-E uses the standard European mobile telephone frequency bands; 890-915 MHz and 935-960 MHz. The channel bandwidth is 25 kHz that provides 1,000 channels. The MATS-E is a frequency duplex system separated by 45 MHz. Each cell site has at least one dedicated control channel with a signaling rate of 2400 bps. Voice channels use FM modulation with sub-band digital audio signaling with a data rate of 150 bps
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