OpenSignal: GSM WCDMA LTE WI-FI - 2G 3G 4G (Cell Coverage) Signal Maps

Here at telecomHall, as you already know, we share tips and interesting suggestions geared to the technical audience, people who works with Telecom and IT. But today we are going to talk about a very interesting application, but that doesn't only apply to these professionals, but to everyone that use wireless devices.
Introducing OpenSignal, an application that performs Cellular and Wi-Fi Networks data collection, and use it in building a comprehensive public map with information for all these networks around the World.

And gets it through a technique that should be increasingly exploited in other applications: the collaboration of all users, with beneficial results to all.

Then, let's go to see the application?

UMTS/GSM/LTE/CDMA/EVDO Network Monitor and Drive Test tool

This is a fieldtest/netmonitor application for UMTS/GSM/LTE/CDMA/EVDO network.

The application monitors the serving CELLID, LEVEL, QUAL, MCC, MNC, LAC, technology, cell serving time and neighbor cells CELLID/PSC and LEVEL.

LEVEL and QUAL depend on technology:
- 2G - RXLEVEL and RXQUAL
- 3G - RSCP and ECNO
- 4G - RSRP and RSRQ

Only for 4G also SNR and CQI are monitored.
The reported measurements depend on the phone and are not available on all mobiles. For example most phones do not report RXQUAL on GSM and only some report ECNO on 3G.

Multiple Reuse Pattern Technology

 Basic Principle

According to multiple reuse pattern (MRP), the carriers are divided into several groups. The carries in each group work as an independent layer, and each layer uses a different frequency reuse pattern. During frequency planning, you can configure the carriers layer by layer, with reuse aggressiveness increases layer by layer.

MRP has no special requirement on hardware. It is developed from the concept of carrier layering. That is, the available channel numbers are divided into multiple groups, and each group works as a carrier layer. According to the rules of the aggressive frequency reuse pattern, the channel numbers allocated for each layer are listed in Table:

Channel number allocation for each layer

Layer	Channel number
BCCH	n1
TCH 1	n2
TCH 2	n3
…	…
TCHm-1	nm
Note: n1 ≥ n2 ≥ n3 ≥ n4 ≥…≥nm.

For MRP, first you must divide an available band into several sub-bands. Generally, the sub-bands work as the bands for BCCH. The reasons are listed below:

Logical Channels and Channel Mapping

Introduction
In GSM divides up each ARFCN into 8 time slots.These 8 timeslots are further broken up into logical channels.
Logical channels can be thought of as just different types of data that is transmitted only on certain frames in a certain timeslot.

Different time slots will carry different logical channels, depending on the structure the BSS uses.
There are two main categories of logical channels in GSM:

Signaling Channels
Traffic Channels (TCH)

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Signaling Channels

These are the main types of signaling Channels:Broadcast Channels (BCH) - Transmitted by the BTS to the MS. This channel carries system parameters needed to identify the network, synchronize time and frequency with the network, and gain access to the network.

Common Control Channels (CCH) - Used for signaling between the BTS and the MS and to request and grant access to the network.

Standalone Dedicated Control Channels (SDCCH) - Used for call setup.

Associated Control Channels (ACCH) - Used for signaling associated with calls and call-setup. An ACCH is always allocated in conjunction with a TCH or a SDCCH.

*keep in mind, these are only categories of logical channels, they are not logical channels themselves.

The above categories can be divided into the following logical channels:

Broadcast Channels (BCH)
     Broadcast Control Channel (BCCH)
     Frequency Correction Channel (FCCH)
     Synchronization Channel (SCH)
     Cell Broadcast Channel (CBCH)

Common Control Channels (CCCH)
     Paging Channel (PCH)
     Random Access Channel (RACH)
     Access Grant Channel (AGCH)

Standalone Dedicated Control Channel (SDCCH)
     Associated Control Channel (ACCH)
     Fast Associated Control Channel (FACCH)
     Slow Associated Control Channel (SACCH)

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Let's examine each type of logical channel individually.

Broadcast Channels (BCH)

Broadcast Control Channel (BCCH) - DOWNLINK - This channel contains system parameters needed to identify the network and gain access. These paramters include the Location Area Code (LAC), the Mobile Network Code (MNC), the frequencies of neighboring cells, and access parameters.

Frequency Correction Channel (FCCH) - DOWNLINK - This channel is used by the MS as a frequency reference. This channel contains frequency correction bursts.

Synchronization Channel (SCH) - DOWNLINK - This channel is used by the MS to learn the Base Station Information Code (BSIC) as well as the TDMA frame number (FN). This lets the MS know what TDMA frame they are on within the hyperframe.

Cell Broadcast Channel (CBCH) - DOWNLINK - This channel is not truly its own type of logical channel. The CBCH is for point-to-omnipoint messages. It is used to broadcast specific information to network subscribers; such as weather, traffic, sports, stocks, etc. Messages can be of any nature depending on what service is provided. Messages are normally public service type messages or announcements. The CBCH isnt allocated a slot for itself, it is assigned to an SDCCH. It only occurs on the downlink. The CBCH usually occupies the second subslot of the SDCCH. The mobile will not acknowledge any of the messages.

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Common Control Channels (CCCH)

Paging Channel (PCH) - DOWNLINK - This channel is used to inform the MS that it has incoming traffic. The traffic could be a voice call, SMS, or some other form of traffic.

Random Access Channel (RACH) - UPLINK This channel is used by a MS to request an initial dedicated channel from the BTS. This would be the first transmission made by a MS to access the network and request radio resources. The MS sends an Access Burston this channel in order to request access.

Access Grant Channel (AGCH) - DOWNLINK - This channel is used by a BTS to notify the MS of the assignement of an initial SDCCH for initial signaling.

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Standalone Dedicated Control Channel (SDCCH) - UPLINK/DOWNLINK - This channel is used for signaling and call setup between the MS and the BTS.

Associated Control Channels (ACCH)

Fast Associated Control Channel (FACCH) - UPLINK/DOWNLINK - This channel is used for control requirements such as handoffs. There is no TS and frame allocation dedicated to a FAACH. The FAACH is a burst-stealing channel, it steals a Timeslot from a Traffic Channel (TCH).

Slow Associated Control Channel (SACCH) - UPLINK/DOWNLINK - This channel is a continuous stream channel that is used for control and supervisory signals associated with the traffic channels.

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Signaling Channel Mapping

Normally the first two timeslots are allocated to signaling channels.

Remember that Control Channel (aka signaling channels) are composed of 51 TDMA frames. On a time slot Within the multiframe, the 51 TDMA frames are divided up and allocated to the various logical channels.

There are several channel combinations allowed in GSM. Some of the more common ones are:
FCCH + SCH + BCCH + CCCH
BCCH + CCCH
FCCH + SCH + BCCH + CCCH + SDCCH/4(0..3) + SACCH/C4(0..3)
SDCCH/8(0 .7) + SACCH/C8(0 . 7)

FCCH + SCH + BCCH + CCCH

Downlink


Uplink

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BCCH + CCCH

Downlink


Uplink

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FCCH + SCH + BCCH + CCCH + SDCCH/4(0..3) + SACCH/C4(0..3)

The SACCH that is associated with each SDCCH is only transmitted every other multiframe. Each SACCH only gets half of the transmit time as the SDCCH that it is associated with. So, in one multiframe, SACCH0 and SACCH1 would be transmitted, and in the next multiframe, SACCH2 and SACCH3 would be transmitted. The two sequential multiframes would look like this:


Downlink


Uplink

You will also notice that the downlink and uplink multiframes do not align with each other. This is done so that if the BTS sends an information request to the MS, it does not have to wait an entire multiframes to receive the needed information. The uplink is transmitted 15 TDMA frames behind the downlink. For example, the BTS might send an authentication request to the MS on SDCCH0 (downlink) which corresponds to TDMA frames 22-25. The MS then has enough time to process the request and reply on SDCCH0 (uplink) which immediately follows it on TDMA frames 37-40.

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SDCCH/8(0 .7) + SACCH/C8(0 . 7)

Once again, the SACCH that is associated with an SDCCH is only transmitted every other multiframe. Two consecutive multiframes would look like this:


Downlink


Uplink

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Traffic Channels (TCH)

Traffic Channels are used to carry two types of information to and from the user:

Encoded Speech
Data

There are two basic types of Encoded Speech channels:

Encoded Speech - Encoded speech is voice audio that is converted into digital form and compressed.
    Full Rate Speech TCH (TCH/FS) - 13 kb/s
    Half Rate Speech TCH (TCH/HS) - 5.6 kb/s

Data - Data refers to user data such as text messages, picture messages, internet browsing, etc. It includes pretty much everything except speech.

    Full rate Data TCH (TCH/F14.1) - 14.4 kb/s
    Full rate Data TCH (TCH/F9.6) - 9.6 kb/s
    Full rate Data TCH (TCH/F4.8) - 4.8 kb/s
    Half rate Data TCH (TCH/F4.8) - 4.8 kb/s
    Full rate Data TCH (TCH/F2.4) - ≤2.4 kb/s
    Half rate Data TCH (TCH/H2.4) - ≤2.4 kb/s

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Traffic Channel Mapping

Time slots 2 through 7 are normally used for Traffic Channels (TCH)

Traffic Channel Multiframes are composed of only 26 TDMA frames. On each multiframe, there are 24 frames for Traffic Channels, 1 frame for a SACCH, and the last frame is Idle. Remember that a MS (or other device) only gets one time slot per TDMA frame to transmit, so in the following diagrams we are looking at a single time slot.

Full Rate Traffic Channel (TCH/FS)

When using Half-Rate Speech Encoding (TCH/HS), the speech encoding bit rate is 5.6 kb/s, so one time slot can handle two half-rate channels. In this case, one channel will transmit every other TDMA frame, and the other channel would be transmitted on the other frames. The final frame (25), which is normally used as an Idle frame, is now used as a SACCH for the second half-rate channel.

Half Rate Traffic Channel (TCH/HS)

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ARFCN Mapping

This diagram shows a sample Multiframe with logical channels mapped to time slots and TDMA frames. This is just one possible configuration for an ARFCN.
*For illustrative purposes, half of the traffic channels are full-rate and the other half are half-rate

TS0
TS1
TS2
TS3
TS4
TS5
TS6
TS7
*Remember that CCH Multiframes have 51 frames and TCH Multiframes only have 26. Their sequences will synchronize every superframe.

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Offset

Even though GSM uses a full duplex radio channel, the MS and the BTS do not transmit at the exact same time. If a MS is assigned a given time slot, both the MS and the BTS will transmit during that given time slot, but their timing is offset. The uplink is exactly 3 time slots behind the downlink. For example, if the MS was allocated a TCH on TS3, the BTS would transmit when the downlink is on TS3 and the MS is set to receive on TS3. At this point, the uplink is only on TS0. Once the uplink reaches TS3, the MS would begin to transmit, and the BTS is set to receive on TS3. At this point, the downlink would be at TS6. When the MS is not transmitting or receiving, it switches frequencies to monitor the BCCH of adjacent cells.

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Speech Data Throughput

When looking at a Time slot allocated to a TCH, you will notice that TCH does not occur on every single frame within a time slot. There is one reserved for a SACCH and one that is Idle. So, in a TCH Multiframe, only 24 of the 26 frames are used for traffic (voice/data). This leaves us with a data throughput of 22.8 kb/s.

Here is the math:

1. Calculate bits per TCH Multiframe:
We know that there are 114 bits of data on a single burst, and we know that only 24 of the 26 frames in a TCH multiframe are used to send user data.
114 bits × 24 frames = 2736 bits per TCH multiframe

So, we know that on a single timeslot over the duration of one TCH multiframe, the data throughput is 2736 bits.

2. Calculate bits per millisecond (ms):
From step one above, we know that the throughput of a single TCH multiframe is 2736 bits. We also know that the duration of a TCH multiframe is 120ms.
2736 bits / 120 ms = 22.8 bits per millisecond

3. Convert milliseconds (ms) to seconds:
Now we need to put the value into terms of seconds. There are 1000 milliseconds in a second, so we simply multiply the value by 1000.
22.8 bits/millisecond × 1000 = 22,800 bits per second (22.8 kb/s)

4. Convert bits to kilobits:
Finally, we want to put it into terms of kilobits per second, wich is the most common term for referring to data throughput. We know a kilobit is 1000 bits, so we simply divide the term by 1000.
22,800 bits/s ÷ 1000 = 22.8 kb/s

So now we see why the data throughput of a single allocated timeslot is 22.8 kb/s.

There is an easier method to come to this number:

We know that only 24 of the 26 frames carry data, so we can say that the new throughput would be 24/26 of the original throughput. If we convert this to decimal form:
     24÷26 = .9231

We know from the TDMA Tutorial that the data throughput of a single timeslot is 24.7 kb/s. Apply this 24/26 ratio to the 24.7 kb/s throughput:
     24.7 × .9231 = 22.8 kb/s

You can see that we get the same answer as above.

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A single BTS may have several Transceivers (TRX) assigned to it, each having its own ARFCN, each ARFCN having 8 time slots.

The logical channels that support signaling will normally only be on one ARFCN. All of the other ARFCNs assigned to a BTS will allocate all 8 time slots to Traffic Channels, to support multiple users.

The following diagram is an example of how a medium-sized cell might be set up with 4 TRX (ARFCNs).

Sample Medium-Size Cell

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Frequency Hopping

Each radio frequency Channel (ARFCN) is influenced differently by propagation conditions. What affects channel 23 may not affect channel 78 at all. Within a given cell, some frequencies will have good propagation in a certain area and some will have poor propagation in that area. In order to take advantage of the good propagation and to defeat the poor propagation, GSM utilizes frequency hopping. Frequency hopping means that a transceiver hops from one frequency to another in a predetermined sequence. If a transceiver hops through all of the avilable frequencies in a cell then it will average out the propagation. GSM uses Slow Frequency Hopping (SFH). It is considered slow becuase the system hops relatively slow, compared with other frequency hopping systems. In GSM, the operating frequency is changed every TDMA frame.

The main reason for using slow frequency hopping is because the MS must also change its frequency often in order to monitor adjacent cells. The device in a transceiver that generates the frequency is called a frequency synthesizer. On a MS, a synthesizer must be able to change its frequency within the time frame of one time slot, which is equal to 577 µs. GSM does not require the BTS to utilize frequency hopping. However, a MS must be capable of utilizing frequency hopping when told to do so.

The frequency hopping and timing sequence is known as the hopping algorithm. There are two types of hopping algorithms available to a MS.

- Cyclic Hopping - The transceiver hops through a predefined list of frequencies in sequential order.

- Random Hopping - The transceiver hops through the list of frequencies in a random manner. The sequence appears random but it is actually a set order.

There are a total of 63 different hopping algorithms available in GSM. When the MS is told to switch to frequency hopping mode, the BTS will assign it a list of channels and the Hopping Sequence Number (HSN), which corresponds to the particular hopping algorithm that will be used.

The base channel on the BTS does not frequency hop. This channel, located in time slot 0, holds the Broadcast Control Channels which the MS needs to monitor to determine strength measurements, determine access parameters, and synchronize with the system.

If a BTS uses multiple transceivers (TRX) then only one TRX will hold the the Broadcast Channels on time slot 0. All of the other TRXs may use time slot 0 for traffic or signaling and may take part in the frequency hopping.

There are two types of frequency hopping method available for the BTS: synthesizer hopping and baseband hopping.

• Synthesizer Hopping - This requires the TRX itself to change frequencies according to the hopping sequence. So, one TRX would hop between multiple frequencies on the same sequence that the MS is required to.
• Baseband Hopping - In this method there are several TRX and each one stays on a fixed frequency within the hopping frequency plan. Each TRX would be assigned a single time slot within a TDMA frame. For example, time slot 1 might be assigned to TRX 2 in one TDMA frame and in the next TDMA frame it would be assigned to TRX 3, and the next frame would be TRX 3. So, the data on each time slot would be sent on a different frequency each frame, but the TRXs on the BTS do not need to change frequency. The BTS simply routes the data to the appropriate TRX, and the MS knows which TRX to be on for any given TDMA frame.

Baseband Frequency Hopping

• Antenna Installation and Downtilting

When we talk about antenna then we need to understand about antenna installation and specially about antenna downtilting.lets assume that antenna installed then how you can change its position.

Its two types:

1.  left-right = its called azimuth change
2. up-down = its called tilt change.

Lets understand from start.
ANTENNA INSTALLATION

• Antenna installation configurations depend on the operators preferences.

• GSM Interface and Channel Usage

Objectives

On completion of this module you will be able to ...

• comprehend how the various types of information like speech and data are transmitted from the GSM network to the customer's mobile station.
• list and describe the technological details of the terrestrial interfaces in the Base Station Subsystem.
• explain the basics of radio transmission.
• explain and describe the particular importance of the GSM air interface from a technological point of view.
• define the functions of the different radio channels.
• understand and describe the effects of technologies like channel coding and DTX on speech and noise quality in GSM. 

Content

4.1	The BSS Interfaces
4.2	The A Interface
4.3	The A-ter Interface
4.3.1	Fullrate Speech Codec
4.3.2	Discontinuous Transmission
4.4	The A-bis Interface
4.5	The Terrestrial Interfaces - Summary
4.6	The Air Interface Um
4.6.1	Basic Principles of Transmission
4.6.2	The Physical Channels
4.6.3	The Logical Channels
4.7	Channel Coding

4.1 The BSS Interfaces

Within the BSS, the user- and signalling data is transported over a series of interfaces. The A interface connects the Mobile Services Switching Center (MSC) with the Transcoder TC.

The A-ter interface connects the Transcoder with the Base Station Controller (BSC). The A-bis interface connects the BSC with the Base Transceiver Station (BTS). Finally, the data is transmitted to the mobile station via the air interface Um.

Let's consider the PCM30 configuration as an example for the frame structure of data transmission between the MSC and the mobile station, to understand the dataflow at the A interface, the A-ter, A-bis and Um interfaces.

We see that the 4 A-links are mapped onto one A-ter link. 4 A-channels of 64 kbps each are mapped onto an A-ter channel consisting of 4 subchannels of 16 kbps each. In total, the 128 channels of 4 A-links are reduced to the 32 channels of one A-ter link, which are numbered consecutively from 0 to 31. The SS7 signalling, which in our example is to be found in timeslot No 16, is transmitted from A to A-ter transparently, i.e. unchanged.

The frame structure consisting of 32 channels is also found at the A-bis interface. Channel 0 is used for synchronization, the remaining 31 channels transmit warning information for operation and maintenance of the BTS, known as O&M alarms, as well as signalling and voice data. Finally, the information from A-bis is transmitted to the air interface Um via the TRXs, the radio transceivers of the BTS. Two A-bis channels of 4 subchannels each correspond exactly to the eight timeslots of a TDMA frame, which carries the data to the mobile station. A TDMA frame, which we will discuss in more detail later in the course, portions the stream of physical channels or timeslots on a particular carrier frequency into periods.

Its timeslots are numbered consecutively from 0 to 7, and can be assigned to one TRX.

4.2 The A Interface

The A-interface transmits user and signalling data between the MSC and the transcoder. It's the second completely standardized interface in GSM after the air interface. As an open interface it is not tied to a specific producer.

The A-interface is an ISDN-S2M interface that has been adjusted to GSM with a data rate of 64 kbps per timeslot. In the PCM30 configuration, the A interface contains 30 traffic channels. Timeslot number 0 takes over synchronization tasks, and timeslot number 16 contains signalling information in the No 7 signalling system format, or SS7. Thus the air interface has an overall bit rate of 2048 kbps.

The PCM24 configuration, which is generally used in the USA, uses 24 traffic channels. In both configurations, each frame has clearly defined channels for signalling and synchronisation information.

4.3 The A-ter Interface

4 traffic channels of the A interface are bundled into four A-ter channels of 16 kbps each, which are subsequently transmittted to the BSC in a 64 kbps physical A-ter timeslot.

Conversely, signals coming from the BSC are transcoded from 16 to 64 kbps, which is the bit rate typically used in fixed networks. Signalling channels are not transcoded. At the A-ter interface, 120 speech channels of 16 kbps each form a 2 Mbit/s multiplex connection. Four times as many A links as A-ter links are necessary to transmit the same amount of voice data.

4.3.1 Full rate Speech Codec

Now let's turn to a procedure which takes the original speech, and generates the speech description parameters in the TC.

During the first phase of GSM, which lasted until 1995, a speech codec in the MS and in the transcoder was specified as the Full-Rate Codec. The basic characteristics of speech, that is the volume, the base frequency, and the tone, are extracted in 20 ms segments from the 64 kbps signal so that descriptive parameters in 16 kbps signals are generated. The prediction algorithms, that is to say the calculability of speech, make the data less sensitive to the interference a signal meets on its way from and to the mobile station at the air interface.

4.3.2 Discontinuous Transmission

In GSM, all voice signals are transmitted the same way and in a continuous data stream. The channel is occupied even during silence intervals. This has two fundamental disadvantages:

1. Since the mobile station must send for the whole duration of the call, transmitting power is used even in silence intervals, i.e. when the subscriber is only listening. This wastes the mobile station's battery power.
2. Other subscribers using the same frequency in distant cells could be disturbed more than necessary.

Therefore it is logical to switch off the sender whenever the subscriber is not actively transmitting information. Considering the pauses in the dialogue, and also the pauses between and within the sentences, we will find that the average occupation of the radio link is less than 40%.

Discontinuous Transmission (DTX) is a remedy to this problem..

In DTX, a function known as voice activity detection switches off the sender of a mobile station whenever there is no data to be transmitted.

During speech pauses, a "stopgap" in the receiver, which in the uplink is the corresponding transcoder element in the TC, must simulate a functioning channel for the user. In GSM this is called "comfort noise". It is the background noise analysed before the MS is switched off, re-generated by the TC. The comfort noise is even updated during a speech pause, by the mobile station transmitting relevant information to the TC.

4.4 The A-bis Interface

The A-bis interface connects the Base Transceiver Station (BTS) with the Base Station Controller (BSC). In the PCM30 configuration, the data at this interface is transmitted via cable or via microwave transmission at a bit rate of 2 Mbit/s. A cable connection is more resistent to interference, but a network operator must lease it from a fixed network operator.

The microwave links can be operated independently, and are easily configured by the network operator, but they are more sensitive to interference. 4 types of information can be transmitted over the A-bis interface: user information, synchronisation data, signalling information, and data for the operation and maintenance of the BTS, known as O&M alarms.

In the basic configuration, the channels of the A-bis interface are directly connected to the timeslots of the radio transmission at the air interface. The physical data rate is 64 kbps. In PCM30, timeslot 0 of the A-bis interface is used for synchronization. The remaining 31 timeslots of the PCM30 configuration carry data from and to the transceivers of the BTS, as well as signalling information and O&M alarms.

In the uplink, 4 traffic channels of 16 kbps each are sub-multiplexed and transmitted from the BTS to the BSC in a physical A-bis time slot. The same happens in the downlink, only in the opposite direction, i.e. from the BSC to the transceivers of the BTS.

Today's BSC - BTS connection can also be configured as a dynamic link with variable signaling and traffic time slots, according to the current traffic situation.

Two PCM30 channels can be assigned to one TRX. These channels consist of 4 sub-timeslots each. Each PCM30-subtimeslot corresponds to a timeslot in the TRX. Thus, by mapping 8 PCM30 sub-timeslots onto one TDMA frame consisting of timeslots 0 to 7, the entire TDMA frame of the TRX would theoretically be available for the transmission of payload data. But then there wouldn't be enough space left for the necessary signalling traffic from and to the mobile stations. According to a fixed, producer-, and configuration-specific pattern, the signalling information is carried in specific A-bis timeslots of 64 kbps each, or in 16 kbps sub-timeslots, to at least 1 TRX per cell, where it uses timeslot 0 to be transmitted over the air interface.

Special timeslots carry the O&M alarm traffic between the OMC and the BTS over the BSC. The information is, of course, not transmitted over the air interface. As we could see at the A-ter interface, each 16 kbps of a traffic channel consist of 13 kbps of payload and 3 of inband signalling between the BTS and the transcoder.

Only the 13 kbps of payload data may be transmitted over the air interface.

Depending on the producer, and on the configuration, each A-bis connection in the PCM30 configuration may transport user information, signalling information, and O&M information from and to up to 15 transceivers.

In the PCM24 configuration, 24 channels achieve an overall bit rate of 1536 kbps at the A-bis interface. Up to 10 transceivers can be assigned to a connection.

4.5 The Terrestrial Interfaces – Summary

Let's summarize what we have learned about the three terrestrial interfaces A, A-ter and A-bis:

Each of these three interfaces transmits information for the synchronization of the individual network elements point-to-point, at a data rate of 64 kbps, and using timeslot 0.

The transcoder merely forwards the SS7 signalling between the MSC and the BSC. This is done transparently, at a bit rate of 64 kbps, both over the A and over the A-ter interface, for example in timeslot 16. The TRX-related signalling between the BSC and the BTS is transmitted over the A-bis interface at 16, 32 or 64 kbps, depending on the producer. O&M alarms from the transcoder are transmitted to the BSC over the A-ter interface at 16 kbps, or as inband signals through a normal traffic channel. O&M alarms from the BTS are transmitted to the BSC, which is also the O&M master for the entire BSS, over the A-bis interface at 16 or at 64 kbps. If the BSC is unable to correct the errors that caused the alarms, or if it detects an error within itself, it informs the OMC directly, or forwards the alarms from the BTS or TC to it.

Let's consider the transmission of speech and user data, which is transmitted at a data rate of 64 kbps over the A interface, at 16 kbps over the A-ter interface - after being turned into transcoded speech or rate adapted data - and also at 16 kbps per subchannel over the A-bis interface. SMS messages are transmitted via signalling channels. The number of physical timeslots that's available for the transmission of signalling information over the air interface depends on the configuration, and is up to the manufacturer or to the operator.

4.6 The Air Interface Um

Within mobile radio networks, data is transmitted over PCM lines at a bit rate of 2 Mbit/s. Air transmission is used between the mobile station and the BTS, and the information transmitted over the air interface must be adjusted to the PCM lines so it can pass through the rest of the network. The air interface, or Um, is the weakest part of a radio link. In GSM, a lot is done to ensure high quality, security, and reliability. 

At the air interface, the frequencies are arranged in pairs. Each uplink frequency has a downlink frequency permanently assigned to it. The uplink signal goes from the mobile station to the base station, and the downlink signal goes in the opposite direction - from the base station to the mobile. The arrangement in pairs is what actually enables simultaneous communication. The difference between the frequency pair is fixed and is called "duplex frequency". In GSM 900, the duplex frequency is 45 MHz. Accordingly, the uplink frequency range 890 to 915 MHz, is assigned to a frequency range of 935 to 960 MHz in the downlink. In GSM 1800, the duplex frequency is 95 MHz. The uplink frequency range lies between 1710 and 1785 MHz, the downlink frequency range between 1805 and 1880 MHz. In GSM 1900, the duplex frequency is 80 MHz. The uplink frequency lies between 1850 and 1910 MHz, and the downlink frequency between 1930 and 1990 MHz.

4.6.1 Basic Principles of Transmission

The BTS elements which send and receive radio signals in the downlink and uplink channels, are known as transmitter & receivers, or transceivers (TRX) for short. In GSM networks, the transmission over the air interface is digital. Digital transmission in GSM is based on a combination of the FDMA- and the TDMA methods, which already have been introduced. In Frequency Division Multiple Access - or FDMA - different frequency channels are assigned to each BTS. Mobile phones in neighbouring cells - or within the same cell - can be used simultaneously, but occupy different frequencies. The FDMA method uses different carrier frequencies - 124 in GSM 900, 374 in GSM 1800, and 299 in GSM 1900.

4.6.1 Basic Principles of Transmission

Time Division Multiple Access, or TDMA, is a method where several subscribers share one frequency - each subscriber is assigned its own time unit, which is known as a timeslot. In analog mobile systems, on the other hand, a frequency is occupied by one subscriber for the duration of the call. In TDMA systems, each mobile station sends and receives information only on the timeslot it has been assigned. These timeslots are either used to transmit voice data, or information on signalling and synchronization

To send digital information over the air interface, the analog radio signals must be interpreted as bit signals. This process - the transmission of digital information to the air interface - is called modulation. Modulation takes advantage of the physical characteristics of analog signals, and changes them in a certain way, depending whether the digital value to be transmitted is 1 or 0. Signals can be modulated on the basis of their amplitude, their frequency, or their phase. GSM uses a specific phase modulation known as the Gaussian Minimum Shift Keying, or GMSK.

Time Division Multiple Access, or TDMA, splits a radio frequency into consecutive periods known as TDMA frames. A TDMA frame, in turn, consists of 8 short time units, which are referred to as time slots. These time slots represent the physical basis for data transmission. Therefore they are also called physical channels. The radio signal between the mobile station and the BTS consists of a continuous stream of time slots, organized in TDMA frames. Each connection is always assigned one timeslot.

Thus, the physical channels provide the resources used to transmit specific types of information. The types of information and the functions define the logical channels. The logical channels differ according to the function they fulfil in data transmission.

To organize the radio transmission, various frame types consisting of numbered timeslots are specified in GSM. The numbered timeslots are continuously numbered off by the mobile station.

A simple TDMA frame consists of eight physical channels, or timeslots. A timeslot is 0.557 ms long. Thus a simple TDMA frame is 4.62 ms long. The length of a timeslot is also referred to as the burst period. A burst is the content of a physical channel.

Information is transmitted as bursts each TDMA frame period. Traffic channels, i.e. time slots 0 to 7 in a basic TRX configuration, contain their information organised in 26 TDMA periods of time known as a multi-frame. This is 26 x 4.62 ms = 120 ms long. Signaling information, normally provided in time slot 0, is organised in 51 TDMA periods of 4.62 ms each, which makes 235 ms altogether. 26 of these "long" 51-multiframes, or 51 of the "short" 26-multiframes form a superframe, which is 6.12 seconds.

The largest transmission unit defined is the hyperframe, which contains 2,048 superframes and is 3 hours, 28 minutes, 53 seconds, and 760 ms long. TDMA frames, multiframes, superframes and the hyperframe can be considered as counters to organize user and signalling information within the TRX, and to support cyphering at the air interface.

4.6.2 The Physical Channels

The information which is physically transmitted over the air interface Um via the physical channels must be converted into a 16 kbps signal within a 2 Mbit/s Frame, which connects the BTS and the BSC as the A-bis interface. It is very important that all mobile stations within a cell send their digital information at the right moment, in order to avoid collisions at the timeslots of the air interface, which would destroy the transmitted information. Therefore, each mobile station sends its digital voice data at regular periodic intervals, using a different timeslot to the other mobile stations within the same cell. The medium for this transmission process is the timeslots, or physical channels. The content of such a channel is also known as a burst. Bursts consist of different data blocks containing payload- as well as security information, to guarantee high data reliability and transmission quality.

4.6.3 The Logical Channels

In GSM, there are two types of logical channels: the dedicated channels, and the common channels. Let's explain the difference between the two with a metaphor from gardening. If we want to water a whole area, and not a particular plant in it, we use a watering can.

This metaphor describes the common channels. These supply their data according to the principle of "equal shares for all", and are not directed to a specific target. They are used to broadcast information area-wide to all the mobile stations within the service area of a BTS. This is general signaling information, for example to log onto the network and cell-broadcast SMS.

If, on the other hand, we only want to water a specific plant and deliberately leave out the neighbouring ones, we use a jet of water. This metaphor corresponds to the Dedicated Channels. These are always directed to a particular addressee. Various types of signalling channels, known as the dedicated control channels, facilitate communication between the mobile station and the mobile radio network. And, of course, traffic channels that carry user speech and data also belong to this category. To understand the tasks of the individual logical channels, we will now look at how a mobile station logs on to the network.

After the subscriber has switched on his mobile station and typed in his PIN code, the mobile station searches for a network. But how does it log on to the network the subscriber is registered with? For this purpose, the BTS sends out the Frequency Correction Channel (FCCH) at short regular intervals, to help the mobile station find a frequency for downlink reception and adjust its frequency oscillator for the uplink transmission. To do so, it picks out the strongest received signal. The Synchronization Channel (SCH) then helps the mobile station to synchronize itself to timeslot 0 sent out by the BTS. This means the mobile station must adjust to the rhythm given by the BTS.

The SCH contains the TDMA frame number as well as the Base Station Identity Code, containing basic information about the network operator that can be compared with the info stored on the SIM card. After this step, the mobile is able to decide whether it has chosen the proper network. If not, it starts the same procedure again trying with the second strongest FCCH received.

While the mobile station uses the FCCH to adjust its frequency, and the SCH for synchronization and network identification, the Broadcast Control Channel (BCCH), which is also sent by the BTS, supplies the mobile station with additional information about the selected cell, for example for ciphering. For some Value Added Services, for example location-dependent services, additional information has to be transmitted from the BTS to the mobile. The Cell Broadcast Channel CBCH is used for this purpose to transmit geographical parameters, for example Gauss-Krueger-Coordinates of the BTS, to the mobile. The FCCH, SCH, BCCH and CBCH are Broadcast Channels, and exist only in the downlink. They are the first logical channels belonging to the Common Channels.

The mobile station has now adjusted its frequency and synchronized its TDMAs, and has picked out the best cell available. But before it can be reached by other subscribers, and before it can initiate calls, a Location Update and authentication procedure are necessary. Only after that is the mobile station logged on to the network and has radio coverage. It can now be reached by other mobile stations, or initiate a call. For this purpose, Common Control Channels are required. Common Control Channels are "point-to-multipoint" channels, which exist either only in the uplink, or only in the downlink.

When a subscriber is called, the Paging Channel (PCH) is broadcast in the downlink by all base stations within a Location Area, so that the mobile station concerned can react. To initiate a call, the mobile station sends out a Random Access Channel (RACH), which carries its identification and request, for example for registration, to the network. This channel only exists in the uplink. In return, the network sends the Access Grant Channel (AGCH) in the downlink direction, to assign resources to the mobile station, by granting it a Stand-Alone Dedicated Control Channel, SDCCH. The PCH, RACH and AGCH form the group of the Common Control Channels belonging also to the Common Channels.

A Stand-alone Dedicated Control Channel (SDCCH) has to be assigned to the mobile station to exchange the requested signaling with the network, for example authentication, ciphering or call set-up. Also, it assigns a traffic channel, and it transmits short messages.

The SACCH is always linked with an SDCCH or a traffic channel. It sends measurement reports to the network, and is used for power control and to handle the exact temporal alignment of the channels, the so-called Timing Advance.

If the subscriber moves into the service area of another BTS, the handover command needed is transmitted over the FACCH. This channel is also used for every call release. During the call, FACCH data is transported over the Traffic Channel assigned.

The Dedicated Control Channels are bidirectional point-to-point channels and belong to the group of Dedicated Channels. 

User speech and data are transmitted over the traffic channels we have already spoken about. Traffic channels are bidirectional, and also belong to the group of dedicated channels.

There are two different channel types supporting different gross bit rates. The Traffic Channel Full rate (TCH/F) has a gross bit rate of 22.8 kbps. It is used for speech encoded by a Full Rate or Enhanced Full Rate codec as well as for user data encapsulating a net bit rate of 9.6 kbps for standard bearer services, 14.4 kbps per timeslot in the case of HSCSD, or up to 21.4 kbps with GPRS. The Traffic Channel Half rate (TCH/H) supports 11.4 kbps and is only used for Half Rate codec speech.

Let us sum up what we just learned about the classification of logical channels. Common channels include FCCH, SCH, BCCH, PCH, RACH, AGCH and, finally, CBCH. All contain point-to-multipoint signaling information.

Dedicated Channels contain point-to-point signalling, such as SDCCH, SACCH and FACCH, or traffic, such as TCH/F and TCH/H.

4.7 Channel Coding 

To be able to detect and correct bit errors at the air interface, GSM performs channel coding. This procedure is organized in two consecutive processes: block coding and convolutional coding.

In block coding, the parameters describing the speech data are first subdivided into three classes, which define if the data is important, required or unimportant for speech intelligibility. With convolutional coding, the information relevant to speech intelligibility is doubled with an arithmetical operation. That means a copy of the data is made so the data can be restored if necessary. This procedure allows to fully compensate bit error rates of up to 12.5 % in the secured relevant data. Channel coding increases the bit rate necessary at the air interface from 13 to 22.8 kbps.