Mobile Phone Technology at a Microscopic
Information System Engineering, Year 2
Article 2 by Rajkumar Periannan,
Supervised by Dr T.Field
Paired with Fadi Joseph Fahham



Programming Subscriber(Mobile) Unit
Control Channel Functions Subscriber Initialization
Subscriber Initialization Call Progression
Call Progression Call Origination and Termination
Mobile To Land Traffic Channel Access
Land to Mobile Maintaining the Link
Call Termination



Fixed Channel Assignment Strategies Forward Channel Concept
Dynamic Channel Assignment Strategies Queueing Handover Request
Flexible Channel Assignment Strategies




Mobile phones....Is it a small electronic device? It looks like a television remote control doesn't it? The way it works is simple isn't it? Yes! Yes! No!!!!! This article explains why the answer to the last question is No by using detailed explanation on how a cellular system processes calls. The cellular network used to explain this has dual mode-digital and analogue(D-AMPS in North America). The call processing events[1] for both analogue and digital cellular system covered here are :-

The call processing events above are explained using various relevant channels. In addition, fo digiatl mode, the problem of maintaining the link is discussed. This is then followed by a description of various channel assignment startegies that can be used to allocate the appropriate channels needed for call processing. Finally, the forced termination problem is discussed and the schemes used to solve this problem(especially the handover request queue shceme) is described in detail and their performance is compared.


In the North American cellular system there are 832 full duplex channels available for use including the expanded spectrum. The 832 channels are divided into two bands. Band A is the non-wireline carrier and band B is the wireline carrier. At the center of these bands are 42 channels dedicated to control purposes. These channels are used for call setup purposes and carry no speech. The remaining 395 channels are voice channels which carry speech.

In describing call processing some new terms will be introduced. Signaling information sent to the mobile is on the Forward Control Channel (FOCC). Signaling information sent to the cell site is on the Reverse Control Channel (REVCC). There is also a Forward Voice Channel (FOVC) for and a Reverse Voice Channel (REVC) for voice communication.

Each mobile contains a memory referred to as a Number Assignment Module(NAM).The NAM contains the mobile's directory number, system parameter information, options and other phone programmable information. This information is programmed into the mobile's memory at the time of sale by the dealer. The mobile's telephone number is referred to as MIN1 and MIN2. MIN1 is the 7 digit office code and unit number while MIN2 is the area code. Another piece of information programmed i-nto the mobile is the cellular system's System Identification Number(SID).

Electronic Serial Number
Another area of the mobile's memory contains the unit's Electronic Serial Number(ESN). This number is unique to each mobile.


Each carrier (non-wireline, wireline) has 21 channels allocated for control purposes. One of these channels is assigned to each cell site. A control channel is on the air 24 hours a day, 365 days a year. The control channel actually combines three functions into one channel:

This is done to reduce the number of channel needed for control purposes to a minimum.

Types of Messages

The information that is continuously transmitted is on the Forward Control Channel (FOCC). Continuos transmission is needed here because the mobile phone monitors the level of the received FOCC to determine when they approach the edge of the cell and needs to be passed to an adjacent cell base station. There are three types of messages that are multiplexed in this channel:
Overhead Messages These are messages that are intended for all mobiles. Information in this message includes the cellular system's SID, combined paging and access channel information, and subscriber registration information.
Mobile Control Messages These messages contain information for a specific mobile. This includes paging data, voice channel assignment, power level, or other commands that cause a mobile to respond.
Control Filler Messages These are messages that are transmitted when there are no other messages to be transmitted on the FOCC. This maintains the mobile's synchronization to the Overhead Message Train. This message can also be used to tell the mobiles what power level to use when accessing the system on the Reverse Control Channel.


Power Up Tests

Before a call can be originated or received, the mobile unit must go through an initialization sequence.

Upon application of power, the mobile does a series of internal diagnostics. Memory is checked and sanity tests are done on the processor(s). A tone is injected into the audio circuitry. If the circuits are good, the tone is heard from the speaker. All indicator lights are activated and "8's" are shown in the display. If any portion of the diagnostic routine fails, the mobile powers down.

Control Channel Access
Next, the mobile scans the 21 control channels looking for an active channel. If it is programmed for the A side it scans from channel 333 down 21 channels. If it is assigned to the B side, it scans from channel 334 up 21 channels. The mobile looks for the strongest control channel and starts decoding the transmitted information. This includes system SID, combined paging and access channel information, and how many channel to scan for paging/access channels. Now the mobile scans the 21 channels a second time. This time it is looking for the strongest paging channel. (It got the number of channels to scan during the first scan.) The mobile now locks onto the strongest paging channel and goes into the "idle task". Although the mobile scanned the 21 control channels a second time looking for a "paging" channel, it actually returned to the same control channel. Control, paging, and access functions are multiplexed onto the same channel.

In the idle task, the mobile is constantly monitoring the overhead message train. It is looking for control information which will most likely be a page of its directory number. It is also scanning its keyboard looking for data entry. This would be when the user makes a call.


This section of Call Processing will deal with various call types. Each of the call types we'll be covering assumes the mobile is in the idle task and in its home system. The first one discussed is the Mobile to Land call.
Before this section is covered there are two signals that the reader needs to know.
They are :-

The SAT acts as a safeguard against co-channel interference. This interference, if stronger than the wanted signal would capture the receiver and an unwanted conversation would intrude, causing annoyance and jeopardizing privacy of voice channels. The SAT consists of three tones each at 5970Hz, 6000Hz and 6030Hz.
Diagram 1
The diagram on the left shows the SAT assignments to cell clusters.

During a call, the mobile phone continuously transmits the SAT assigned to the cluster within which the mobile phone is located. The other two SAT frequencies are assigned to adjacent clusters as shown in diagram 1. Now, if the co-channel interferer is sensed by the base originating from the adjacent cluster, it will carry the wrong SAT and the audio output will be muted.


Mobile to Land Call Flow Chart

When placing a mobile originated call, the dialed digits are keyed in. The mobile does not transmit at this time. This process is called preorigination dialing and the dialed digits are put into memory. The call process starts when the user presses the SEND key.

After the SEND key is pressed, the mobile scans the 21 dedicated control channels looking for a access channel. It should be remembered that control, paging and access functions are on the same channel. The mobile will most likely return to the same control channel it was originally on.

When the mobile locks onto what it recognizes as an access channel it checks the status of the busy/idle bits on the FOCC. A "0" indicates the RECC is busy processing a call. A "1" indicates the channel is available for use. When the mobile sees a "1" status, it transmits a service request on the RECC.

The service request contains the mobile's ESN, dialed digits, and its directory number. After transmitting the service request, the mobile turns off its transmitter and checks the status of the busy/idle bits. If they change from idle to busy within 104 bits, the mobile knows the request was accepted by the cell site. The mobile now waits for a command from the cell site.

When the cell site receives the service request message, it forwards the information to the MSC(Mobile Switching Center). The MSC validates the subscriber's MIN and ESN and translates or routes the call. The cell site selects an idle voice channel and transmits an Initial Voice Channel Designation Message (IVCDM) to the mobile on the FOCC. The IVCDM contains the voice channel number, the associated Supervisory Audio Tone (SAT) for the mobile to transpond, and the Voice Channel Mobile Attenuation Code(VMAC). The selected voice channel turns on its carrier and transmits the cell site's SAT. It is transmitted by the cell site BS, checked by the mobile, and transponded back to the cell site. If SAT is lost for 5 seconds or more in either call direction the call is dropped. VMAC tells the mobile what power level to use once it moves to the assigned voice channel.

The combined information in the service request and IVCDM is used to open a Call Detail Record (CDR). As the call progress, other information is added to the CDR.

After validation and translation, the dialed digit information is sent to the PSTN to connect the landside party. If the mobile were calling another mobile, the MSC (not the PSTN) would process the call.

The event that occurs after the mobile phone receives the IVCDM is considered again. The mobile tunes to the assigned voice channel and sets its transmitter to the assigned power level. It then checks the frequency of the SAT being transmitted on the Forward Voice Channel(FOVC). If it is the same as the SAT it was told to expect in the IVCDM it transponds SAT back to the cell site and unmutes its receive audio. When the cell site receives SAT on the Reverse Voice Channel (REVC) it unmutes its forward audio.

When the cell site detects the transponded SAT from the mobile it knows the mobile is on the assigned voice channel. Both audio paths are enabled and the mobile user hears ringback from the PSTN. When the called party answers conversation begins.

It was mentioned earlier that SAT is transmitted continuously by the base station and transponded by the mobile. This isn't exactly true. During a call control information needs to be transmitted to the mobile. This control information could be power control information or a handover order. In order to digitally transmit this control information without disturbing the voice conversation in progress, blank and burst signaling is used. The audio in the forward direction is muted and the data burst is sent. After completion of the data burst the forward audio is enabled. The mobile user does not hear the data burst during the "blanking" time when the data is sent.


Call Termination Flow Chart
A call can be intentionally terminated by the mobile subscriber or by the other party, either landside or mobile. When the mobile terminates a call (the user hangs up or presses the END key) the unit transmits on the REVC 1.8 seconds of Signal Tone(ST). This tells the cell site that the call is to be brought down. The cell relays this message to the MSC. The MSC informs the PSTN switch to disconnect and the call is brought down. After transmitting the 1.8 seconds of ST, the mobile turns off its transmitter and starts the initialization task.

When the other party initiates the call termination, the MSC recognizes the PSTN side disconnect and sends a message to the cell site to transmit a release order to the mobile. The release order is sent using blank and burst signaling on the FOVC. The mobile responds by sending 1.8 seconds of ST on the REVC and then unkeys its transmitter. The mobile then begins the initialization task.


Land to Mobile Call Flow Chart

When a landside party calls a cellular mobile the PSTN determines that the call must be routed to the MSC. A CDR is opened and the MSC performs validation and translation of the dialed digits.

A page message is sent from the MSC to the system's cell sites. This page message is transmitted on all FOCC in all cell sites. Systems can also be configured so that just the last known paging area the mobile was in will transmit the page message.

When the mobile sees the page on the FOCC it rescans the control channels looking for an access channel and locks on to the strongest one. The mobile checks the busy/idle bits (just like the mobile to land Call scenario) and transmits a page responds message on the RECC.

The cell site receives the page response message and selects an idle voice channel. The selected voice channel keys its transmitter and begins transmitting SAT. The cell site transmits on the FOCC an IVCDM to the mobile that contains the voice channel assignment, SAT, and VMAC information.

When the mobile receives the IVCDM on the FOCC, it tunes to the assigned voice channel, checks and transponds SAT. The MSC updates the CDR with the IVCDM information.

Next, the cell site transmits an alert order on the FOVC to the mobile. This message tells the mobile to start ringing. When the mobile starts ringing, it transmits ST continuously until the mobile is answered. When the mobile goes off hook, ST is shut off. This loss of ST at the cell indicates that the call has been answered. The MSC now connects the landside party with the mobile. Both forward and reverse audio paths are unmuted, conversation takes place, and the CDR is updated.

Landside to mobile call termination was previously discussed under the Call Termination section.


This section will discuss the process the mobile goes through when placing a digital call. There are many areas in the processing of a digital call that is similar to an analog call. This section will concentrate on the differences between the two. A knowledge of analog call processing is assumed.

The call progression description will be centered around a dual mode mobile. This is a mobile (or portable) that is capable of operation in either the analog or digital mode. We will assume the mobile is operating in the digital mode.


The dual mode mobile is programmed almost exactly like the analog phone. The major exception is the Station Class Mark (SCM). This is an entry into the mobile's memory that tells the switch the unit has digital capability. When the phone makes a call origination it tells the switch what type of phone it is.

Power Up Tests

These tests are similar to the analog phone power up tests.

Control Channel Access

After the power up tests, the mobile scans the 21 control channels. It will scan the dedicated 21 control channels, either the A side channels (313-333) or the B side channels (334-354) depending on how the phone is programmed. It will look on the strongest control channel for the Protocol Compatibility Indicator (PCI) bit. This bit tells the mobile whether or not the system has digital capability. If this bit is set, the mobile proceeds with decoding the overhead message train and going into the idle task just as in the analog system. If the PCI bit is not set the phone will scan the secondary control channels for the strongest signal.. These are a second set of control channels that be from 696-716 for system A or 717-737 for system B. These secondary control channels are for digital use only. The phone then attempts to decode a possible overhead message train. If an overhead message train(OMT) cannot be found (this could be an analog voice channel!), the phone retunes to the primary control channels and operates in the analog mode.


Call Origination and Termination

Call progression in these areas are similar to analog operation. A major difference is when the mobile is instructed to tune to a digital traffic channel. In an analog system the mobiles is assigned a voice channel.

If digital traffic channels are available (digital voice/data channels) the base station informs the mobile of the channel and time slot assignment. The mobile is also informed of the Digital Verification Color Code (DVCC) to expect on the traffic channel. The DVCC is an 8 bit word that is transponded on each time slot. It performs the same function as SAT in an analog call. The DVCC word has an additional 4 bits added for error correction to make it a Coded Digital Verification Color Code (CDVCC).

Traffic Channel Access

When the mobile receives the digital traffic channel designation on the Forward Control Channel, it attempts to synchronize to the Forward Digital Traffic Channel. When synchronized, the mobile transmits in its allocated time slot at its assigned power level and will transpond CDVCC.

The signal from the mobile to the base station takes a finite amount of time to travel to the cell site. A special Time Alignment procedure is used to ensure that transmission from other mobiles on the same frequency (but different time slots) do not collide. When the mobile first joins the traffic channel the distance to the base station is not known. The mobile needs to know how much to delay its transmissions in its time slot to avoid collisions, or glare.

Before the mobile starts transmitting actual data, it first transmits Shortened Bursts. This allows the base station to determine time alignment information. The base station sends the mobile timing information until it starts receiving valid data. The mobile then will begin transmitting in its normal mode.


Once the mobile is on the Digital Traffic Channel it will be operating in its assigned time slot and with the proper time alignment. As the mobile moves through the cell's coverage area messages are sent to adjust the mobile's power level and time alignment to maintain call quality.

During a call there are conditions that can cause the call quality to deteriorate. This results in an increasing Bit Error Rate (BER). Some causes can be:

These types of interference can cause both amplitude and phase distortion which will cause an increase in the BER.

Doppler Shift

Doppler shift causes a change in receive frequency when there is relative motion between the base station and the mobile. These frequency (phase) changes in an analog system are relatively minor. However, in a digital system, the Doppler shift can cause problems. A car traveling 60 mph to or from a cell site causes a frequency shift of 80 Hz. The digital modulation scheme interprets this as a phase change and errors can occur.


Fading occurs when the signal form a transmitter is attenuated by physical objects such as a building or a hill. The receiver has an Automatic Gain Control (AGC) circuit to compensate for fading.


Multipath occurs when two or more signals arrive at a receiver at different time because of reflections. There is a time delay between the two signals because each signal traveled a different distance. If the two signals are 180 degrees out of phase, complete cancellation occurs. This is also a concern in analog systems.


As we have seen, there are many factors at work to degrade the digital signal which causes the BER to increase. There are many techniques use to combat these effects such as space diversity to minimize the effects of multipath and AGC to help control fading. But the combined effects of all modes of interference can be to much for the radio to handle. There is one more tool in the arsenal to fight signal equalizer.

In dual mode radios the equalizer compensates for the effects of distortion . The transmitted SYNC word contains a known bit sequence. The receiver takes this known bit sequence and compares it to the received signal. The equalizer can then dynamically adjust its filters to reverse the effects of distortion.

Call Termination

At the end of the conversation one of the parties will go on hook. If the call is on an analog channel the process will be as discussed in the analog call processing section. If the call is on a digital traffic channel, a Release Message will be sent either by the base station or by the mobile, depending on which side of the call goes on-hook first. The receiving end will acknowledge the order, the mobile turns off its transmitter and retunes to the primary control channels. The mobile then starts the initialization procedures.


In the text above, the channels used and the purpose they serve in both analogue and digital cellular system during call processing have been discussed

This section identifies and explains strategies that could be used to assign the needed channels.

The three main assignment strategies are :-

The diagram below shows the sub-strategies existing within the three major assignment strategies stated above


The common underlying theme in all fixed assignment stretegies is the permanent assignment of a set of channels to each cell. The same set of radio frequencies is reused by another cell at some distance away.

(i) Basic Fixed Assignment Strategy

A call attempt at a cell site can only be served by the unoccupied channels of the predetermined set of channels at that cell site(see diagram 2); otherwise, the call is blocked. Here, when handover occurs, the MSC informs the new BS and receive a confirmation or rejection message from the new BS regarding the handover.

Diagram 2
Fixed channel assignment strategy. A-G denote different sorts of channels permanently assigned to cells.


A very high number of users would have their call blocked(blocked traffic). The number of users serviced at any one time is fixed.

The other fixed assignment methods are variations of this basic strategy(see diagram 3).
Diagram 3
Borrowing strategies. channel a4 is borrowed and now locked to cells marked 'N'. Cells marked 'X' were already prohibited from using a4.

(ii) Simple Borrowing Strategy

If all permanent channels of a cell are busy, a channel can be borrowed from a neighboring cell, provided that this channel does not interfere with the existing calls.
When a channel is borrowed, additional cells are prohibited from using it. The MSC supervises the borrowing procedure, following an algorithm that favors channels of cells with the most unoccupied channels to be borrowed. The algorithm 'locks' the borrowed channels towards the cells that are one or two cell unit away from the borrower cells.
The MSC keeps record of free, serving and borrowed(therefore locked) channels and informs all the BSs about locked channels.

A lower call blocking probability up to a certain traffic level.

(iii) Hybrid Channel Assignment Strategy

In this proposed strategy[5], permanent channels of a cell are divided into two groups

The ratio of the numbers of channels in the two group is determined a priori, depending on the estimation of the traffic conditions.
As for the MSC, in addition to its duties in the simple borrowing strategy, now it has to label all channels with respect to the group they belong.

The traffic condition is unlikely to deviate significantly from the predicted figures. But when deviation does occur, channel efficiency could degrade.

(iv) Borrowing with Ordering Strategy

This strategy elaborates on the idea of hybrid assignment by dynamically varying the local-to-borrowable channel ratio according to the changing traffic conditions. Each channel has a different adjustable probability of being borrowed and is ranked with respect to this probability, so that channels toward the bottom of the list are more likely to be borrowed, and vice-versa. Each time a call is attempted, an algorithm at either the MSC or BS is run to choose the most 'appropriate' channel among all free channels, looking at their associated probabilities. The MSC determines and updates each channel's probability of being borrowed based on the traffic conditions, by using an adaptive algorithm.
Minimizes the number of calls on the relatively more 'borrowable' channels in order to reduce the locking effect of borrowed channels in additional cells. This effectively minimizes the number of blocked traffic.


In this strategy, cells have no channels themselves but refer all call attempts to the MSC, which manages all channel assignment in its region. Each time a call attempt arrives, the BS asks the MSC for the channel with the minimum cost to be assigned. The cost function depends on the future blocking probability, usage frequency of the candidate channel, the reuse distance of the channel, and so on. The MSC decides, on a call-by-call basis, which channel to assign to which call attempt by searching for the available channel for which the cost function is minimum.

The MSC needs to have information regarding channel occupancy distribution under current traffic conditions and other network-directed criteria, as well as radio channel measurement
of individual mobile phones.


Flexible channel assignment strategies combine aspects of both the fixed and dynamic strategies because it has two types channels mentioned below :-

Permanent Channel each cell is assigned a set of these channels and would normally suffice under light traffic loads.
Flexible Channel held by the MSC and assigns these to cells whose permanent channels have become inadequate under increasing traffic loads.

There are two ways the MSC can distribute these emergency channels among the cells in need. They are :-
Schedueled manner Assumption is made that future changes in traffic distribution can be accurately pin-pointed in time and space. The change in assignment of flexible channels is then made at the predetermined peaks of traffic change
Predictive manner The traffic intensity or equivalently the blocking probability is constantly measured at every cell site so that the reallocation of the flexible channels can be carried out by the MSC at any point in time

Flexible assignment strategies require the MSC to have up-to-date information about the traffic pattern in its area and other network-directed criteria in order to manage its set of flexible channels efficiently.


This section explains why forced termination of a call occurs and then followed by a discussion of the methods that could be used to minimize this problem.
A break during conversation occurs when handover takes place. This is not noticed by the user. But once the break is thought to become noticable to the user it is forced to terminate.
Call blocking occurs when there are too many users accessing the system simultaneously and the system is unable to allocate free channels to the users.
If the system has a channel assignment strategy in which the BS handles the handover request in exactly the same manner as it handles originating calls, the probability of forced termination of an on-going call due to unsuccessful handover would equal the probability of blocking an originating call. From the user point of view, termination of an on-going call is more undesirable than blocking new calls. Below two prossible handover prioritization scheme is discussed. They are :-

Foward Channel Concept

This scheme improves the probability of successful handovers by simply reserving a number of channels exclusively for handovers. The remaining channels can be equally shared between handovers and originating calls.

There are two problems with this scheme. They are :-

(i) Total carried traffic is reduced since less channels are granted to originating calls(originating calls and not on-going calls add up to carried traffic).
Allow queueing of originating calls

(ii) Risk of inefficient spectrum utilization when fixed channel assignment strategies used.

Use flexible or dynamic channel assignment.Instead of the cells keeping guard channels in their possesion, the MSC should keep a collection of channels dedicated for handover requests, or it can have a number of flexible channels with associated probabilities of being allocated for handover requests.
Queueing Handover Requests

Diagram 4
Handover and receiver thresholds. Linear motion from BS 1 and BS 2 is assumed; handover must occur in [t0,t1]

The handover threshold is set at the point where the power received from a neighbouring cell site has started to exceed the power received from the current Bs for certain amount and/or for a certain time.
The receiver threshold is the point at which the received power from the BS is at the minimum acceptable level.
The overlapping circle area shown in diagram 4 is the handover area. The mobile phone must be assigned a new BS while in the handover area. Call termination occurs when the power level from the current BS falls below the receiver threshold prior to the mobile phone being assigned a channel by the target BS. Therefore the handover request can be queued within the interval in which the mobile phone is in the handover area.

In this section the Measurement Based Prioritization Schemes(MBPS) is discussed. This is then compared with the typical First In First Out(FIFO) scheme.


MBPS is designed as a handover protection method which a cellular communication network can utilize along with any channel allocation startegy. In MBPS, the handover area is divided into power level ratios. This power ratio decreases from the handover threshold to the receiver threshold(decreases when the mobile phone is moved away from the current BS). This is shown in diagram 4.

This scheme uses a multipriority non-preemptive queue.

The properties of this queue are :-

Note : The above mentioned priority allocation is done assuming that the vehicles in which the mobile phone is located is travelling at constant speed.
New calls would only be serviced when this handover request queue is empty. The above mentioned queueing can be performed in the MSC or in the BS. If it is performed in the MSC there should be a seperate queue maintained for each cell. Where the queueing is performed is not a big issue as in both case they serve the same purpose of not serving a request until channel is available.
The flow chart on the left explains the behaviour a system using this scheme. Queue holds the handover requests

Performance comparison with FIFO scheme

Computer simulation[6] have been done to estimate the performance parameters of interest for MBPS and it is compared with those obtained for FIFO scheme using the non-prioritized scheme as a reference.

The performance parameters of interest are :-
(i) Probability of Forced Termination vs offered load at a given handover traffic
Pobability of Forced Termination vs. offered load for 20% handover traffic Probability of Forced Termination vs. offered load for 50% handover traffic


(a) Non-prioritized call handling scheme
This probability is equal to the probability of call blocking at origination(shown in both graphs above and below) since no distinction is made between new call attempt and handover request.
(b) Prioritization scheme
(ii) Call Blocking Probability vs offered load for a given hand over traffic
Pobability of Call Blocking vs. offered load for 20% handover traffic Probability of Call Blocking vs. offered load for 50% handover traffic


(a) Prioritization based scheme
Both FIFO and MBPS shows increase in call blocking compared to the non-prioritization scheme as these schemes are more interested in preventing forced termination. MBPS shows less call blocking compared to the FIFO scheme. This advancement is achieved in MBPS at a less than proportionate cost increase.

Therefore the MBPS compared to the FIFO scheme. The MBPS also has smaller handover queue and smaller service delays[6] compared to the FIFO scheme. CONCLUSION

The call processing event have been discussed in detail for both digital and analogue cellular systems. Various channel assignment strategies have been explained and it was found that an improvement in the channel assignment performance leads to an increase in complexity of the MSC. In order to minimize forced termination of calls, the MBPS should be used instead of the common FIFO queueing scheme. This is because it gives lower probability of call termination and blocked call compared to the FIFO scheme.

AGC Automatic Gain Control
BS Base Station
CDR Call Detail Record
ESN Electronic Serial Number
FOCC Forward Control Channel
FORC Forward Voice Channel
IRCDM Initial Voice Channel Designation Usage
MIN Mobile Identification Number
MSC Mobile Switching Centre
NAM Number Assignment Mobile
REVC Reverse Voice Channel
REVCC Reverse Control Channel
SAT Supervisory Audio Tone
SID System Identification Number
ST Signalling Tone
VMAC Voice Channel Mobile Attenuation Code
1. Title: Mobile Communication Systems
Author(s): Parson J.D., Gardiner J.G.
Source: 2nd Edition, Blackie.
Chapter 8, pg 253.Gives a reasonable explanation about workings of cellular networks.
2. Title: Comparisons of Channel Assignment Strategies in Cellular Mobile Telephone Systems
Author(s): Lee M., T.P. Yum
Source: IEEE Trans. on vehicular Tech., vol 38,Nov. 1989
Detailed explanation of the topic.
3. Title: A strategy for Flexible Channel Assignment in Mobile Communication Systems
Author(s): Tajima J., Imamura K.
Source: IEEE Trans on Vehicular Tech., vol 37, May 1988
Detailed explanation about the topic.
4. Title: Increasing Channel Occupancy in Large-Scale Mobile Radio Systems:Dyanamic Channel Assignment
Author(s): Tajima J., Imamura K.
Source: IEEE Trans on Vehicular Tech., vol 37, May 1988
Detailed explanation about the topic.
5. Title: A Hybrid Channel Assignment Scheme in Large-Scale Cellular Structured Mobile Communication Systems
Author(s): Kanwa T.J., Georganas N.D.
Source: IEEE Trans on Vehicular Tech., vol 26, Apr 1988
Detailed explanation about the topic.
6. Title: An effective Prioritization Scheme for Handovers in Cellular Networks
Author(s): Tekinay S., Jabbari B.
Source: IEEE Communication Magazine
Detailed explanation about the topic.An excellent material