Frequency Hopping (FH) in GSM

Frequency Hopping (FH) is widely used for example in GSM Networks, so let's understand a little more about it today.

First, a Brief History

But before we talk about FH: does who invented it?

Several people competes for this title, as the German Johannes Zenneck in 1908 through his company: Telefunken. He shares the title with a Polish inventor, who also exposed the idea.

But particularly, I like the exotic version, where a beautiful actress (yes) Hedy Lamar, along with her neighbor George Antheil were also responsible, in the Second World War time.

Hedy was married to a German arms manufacturer. Issues like security, especially how to send text messages using a signal that could not be interfered with by the enemy naturally came to mind.

If you send a torpedo controlled by a continuous signal, the signal can be identified by the enemy, which in turn can insert a high noise and shoot it down.

Once at the piano the composer George played a note, and Hedy repeated on another scale. It was then that she realized it was possible to establish a communication by changing the communication channel, just for this, they should make the change at the same time, ie, following a pattern known to both.

Bringing this idea to the torpedo, it sufficed for the transmitter in the vessel and receiver in the torpedo altered (or jumped) from one frequency to another in a synchronized manner. That is, just that the receiver at the torpedo know what are the positions where the transmitter frequency will jump!

And if any of these frequencies are suffering interference? Well, we still have other channels in the sequence of jumps, from where information can be retrieved!

Like any great invention, note that the idea is simple.

Definition

Well, after a brief history, I hope you have understood the idea behind FH.

After the initial contribution of inventors, the idea was perfected, and is now used in various systems such as GSM, as already mentioned.

FH has mainly the purpose of avoiding interference, and we'll see how he gets it.

In FH, the information is spread over a bandwidth much larger than is required for its transmission. For this, it is divided into several channels of lower bandwidth.

Knowing the sequence of jumps that must be followed, the receiver and transmitter jump through these channels.

This is a pseudo-random sequence, and that's what makes the FH also secure, since unwanted receivers can not intercept the signal because they do not know the sequence. The only thing they see are noises of short duration.

For each application with its full range of frequency, it is defined as bandwidth, hop number, and maximum average time that each frequency must be busy.

We should also stress that in FH do not need continuous bands. In scenarios where the available bandwidth is limited and not contiguous, the spectrum can be better used (Actually, this is more a feature comparison between narrowband x broadband systems ).

FH in GSM

Speaking specifically about the GSM now, we'll finally understand how the interference is avoid.

To do so, as always, let us take an example of a network with 10 MHz bandwidth. As the channel of GSM is 200 kHz, we have 50 channels available. Remember that each GSM channel has 8 time slots, and considering Full Rate we have 8 users.

It may seem to many channels, but believe me, a major planning challenge is to spread these channels in a GSM network avoiding interference problems. To illustrate, suppose a network with 100 sectors each BTS 3: we have 300 sectors, and only 50 frequencies. Naturally, the channels must be reused, which inevitably result in the same channels used in different sectors.

And there we have the co-channel interference, a major problem to be solved, especially in dense GSM networks.

Not only the problem of co-channels, we also have the problem of multipath, compounded by the fact that GSM band is narrow. A signal can leave the transmitter, and due to obstacles, be reflected in a way that will eventually interfere with the original signal that arrives at the receiver, since this signal is out of phase, because it had to 'travel' more.

And it is especially in these cases that FH helps us.

For clarity, consider an sector with channels A and B. Hardly all slots of all channels are in use all the time. Even if a particular slot of channel A is also in use in another sector - co-channel interference, chances are that another slot of channel B are not! That's what FH does: changes the frequencies and slots of the call!

Thus, each user runs a much lower risk of suffering co-channel interference.

In other words, a channel can be suffering interference, but we have other channels in the sequence of jumps that may be no interference! When the network uses FH, and moves our call slot to slot, and frequency to frequency, the interference is turns into a random effect.

We still, as we speak, the problems of multipath. And the idea is basically the same. By jumping from one frequency to another, the user suffers the effects of multipath problem by a very small periods of time. (Remember we use narrow bands!)

In both cases, whether co-channel interference or multipath fading, there are the error correction algorithms, which achieve the most efficient way to clean and recover the original signal.

FH Basic Algorithm

Finally, we see a simplified diagram showing the steps involved in establishing a communication using FH.

First, the transmitter sends a request (1) to start the FH through the control channel. The receiver, after receiving this request sends a base number (2) back. The transmitter then uses that number, calculates and sends the series of frequencies (3) to be used. With this list of frequencies, the receiver returns a synchronization signal (4) in the first frequency of the list. Thus, communication between the two is established (5).

Disadvantages

And what are the disadvantages of FH?

Like any spread spectrum communication, we need a bigger band than would be necessary if it were used only a single frequency to carry the signal.

Furthermore, whenever a communication is established, it takes a significant time, to establish sync between the receiver and transmitter.

Anyway, the advantages outweigh these points.

Conclusion

We now know the simple idea of frequency hopping, a spread-spectrum modulation scheme, where it is possible to establish a communication over a single logical channel, based upon the timing of changes (jumps) in frequency among them, following a pseudo-random sequence known by both.

As a result, using the FH have a signal more robust - interference resistant, and secure - to be very difficult to intercept.

OSI BEST METHOD TO UNDERSTAND

Layering

Okay, so here we go: layers. Why this division?

Stages of communication occur in layers. The division - standardization - was made thinking about it, mainly to facilitate the developments. A person can develop technologies to any layer, without having to worry about the others. Interesting, no?

To begin to familiarize ourselves with them, following its listing: Physical (1), Link (2), Network (3), Transportation (4), Session (5), Presentation (6) and Application (7).

But to explain further, it is easier to first make an analogy.

Imagine the following situation, where William, NY - United States sends a letter to Manuel, in Lisbon, Portugal's capital.

Let's start from the transmitter point: William. The first thing that William needs to do is write the letter, along with the Manuel address [7-Application].

William is with his injured hand, and can not write. Then he dictates the contents of the letter to his wife Rose, who writes a letter to Manuel [6-Presentation].

William's wife then put the letter in an envelope, goes to the post, put the letter [Session 5].

Then the postal worker in the United States decides to outsource the service. He asks a third party logistics - Fedex - to carry the envelope, which in turn puts everything in an secure envelope of his Company. [4-Transportation]

The dispatch of the envelope is now on the Logistics company, who decides that the quickest route is to Lisbon Airport - using air. So put the letter in another envelope with your address information, and they take the airline. [3-Network]

Officials of the airline put the envelope in it's company's box on the plane, adding a label with the destination address. [2-Link]

The box with the envelope follows our trip on the plane to Portugal [1-Physics].

Arriving in Portugal, we start the reverse process, ie the reception.

The box is then unloaded from the plane, the envelope is removed from within the same and delivered to an officer who is in charge of directing the envelope to its destination, which is the company Fedex in Lisbon [2-Link].

The delivery of the envelope as we know is with the company Fedex, which verifies that the same should follow for the post office in Lisbon. [3-Network]

An official of the Post Office in Portugal receives the company's FedEx envelope, the envelope of removing it, then deliver to the address of Manuel in Lisbon [4-Transportation].

Mary, the wife of Manuel checks the local post office, and receives the original envelope with the letter. [5-Session].

She then read the contents to him [6-Presentation].

Finally, Manuel learns the news of Willian [7-Application].

This was a very simplified example. We do not talk for example of the routers that may occur, eg if you plane scales, being necessary to add and remove new mailing labels. However, I believe it has served to demonstrate the idea.

Also, remember that all analogy is not always perfect, but helps us understand the idea.

Now that we have done our analogy, we will bring the side a bit more technical, and talk a little about each layer.

We will not follow the entire process - starting from seventh to first, and then the other way. Let's talk at once, taking the road of first layer to last - the seventh.

Note: This description is a long subject, as the description of devices, protocols and aplicatiovs used. Anyway, let's try to keep a simplified line to describe the layers.

Speech Coding

Speech coding is the process of obtaining a compact representation of voice signals for efficient transmission over band-limited wired and wireless channels and/or storage.

Today, speech coders have become essential components in telecommunications and in the multimedia infrastructure. Commercial systems that rely on efficient speech coding include cellular communication, voice over internet protocol (VOIP), videoconferencing, electronic toys, archiving, and digital simultaneous voice and data (DSVD), as well as numerous PC-based games and multimedia applications.

Speech coding is the art of creating a minimally redundant representation of the speech signal that can be efficiently transmitted or stored in digital media, and decoding the signal with the best possible perceptual quality. Like any other continuous-time signal, speech may be represented digitally through the processes of sampling and quantization; speech is typically quantized using either 16-bit uniform or 8-bit companded quantization.

Like many other signals, however, a sampled speech signal contains a great deal of information that is either redundant (nonzero mutual information between successive samples in the signal) or perceptually irrelevant (information that is not perceived by human listeners).
Most telecommunications coders are lossy, meaning that the synthesized speech is perceptually similar to the original but may be physically dissimilar.

A speech coder converts a digitized speech signal into a coded representation, which is usually transmitted in frames. A speech decoder receives coded frames and syn- thesizes reconstructed speech. Standards typically dictate the input–output relationships of both coder and decoder.



Source: From Google

Modulation & Needs of Modulation

Modulation the process of changing some characteristic (e.g. amplitude, frequency or phase) of a carrier wave in accordance with the intensity of the signal is known as modulation. Modulation means to “change”. In another word, it can be said that-“it is the process of combining an audio-frequency (AF) signal with a radio-frequency (RF) carrier wave”. The audio-frequency (AF) signal is also called amodulating wave and the resultant wave produced is called modulated wave. During modulation, some characteristic of the carrier wave is varied in time with the modulating signal and accomplished by combining the two.

Modulator is a one kind of device that performs the modulation. Modulator is necessary for to transmit signal. It can also modify the signal based on the input signal or audio-frequency (AF) signal. Modulators determines at what frequency the system transmits.

Need for modulation:

Modulation is particularly essential in communication system due to the following reason:

• Mutual Interference reduction:

The main purpose of modulation is the reduction of mutual interference. When the signal fed to the transmitter via modulator to the air, the signals are overlap, and then interference occurs. So, modulation is needs to reduce the interference.

• Practical antenna length:

The length of the transmitting antenna should be approximately equal to the wavelength of the wave. Now,

As the audio frequencies range from 20 Hz to 20 KHz, therefore if they are transmitted directly into space, the length of the transmitting antenna required would be extremely large. For instance, to radiate a frequency of 20 KHz directly into space, we would need an antenna length of

This is too long antenna to be constructed practically. For this reason, it isimpracticable to radiate audio signal directly into space. On the other hand, if a carrier wave say of 1000 KHz is used to carry the signal, we need an antenna length of 300 meters only and this size can be easily constructed.

• Operating range:

The energy of a wave depends upon its frequency. The greater the frequency of the wave, the greater the energy the energy possessed by it. As the audio signalfrequencies are small, therefore, these can’t be transmitted over longer distances if radiated directly into space. The only practical solution is to modulate a high frequency carrier wave with audio signal and permits the transmission to occur at this high frequency.

• Wireless Communication:

One popular feature of radio transmission is that it should be carried without wires i.e. radiated into space. At audio frequencies, radiation is not practicable because the efficiency of radiation is poor. However, efficient radiation of electrical energy is possible at high frequencies (>20 Hz).For this reason, modulation is always done in communic

Source: From Google

Telecom-LTE & 3G

Third-generation (3G) wireless systems are deployed all over the world. W-CDMA
maintains a mid-term competitive edge by providing high speed packet access (HSPA) in
both downlink and uplink modes. Typical cell maximum data rate today is around 7.2
Mbps, and typical single-user data rates of around 1.5 Mbps can be expected. To ensure
competitiveness into the future, the long-term evolution (LTE) of the 3rd Generation
Partnership Project’s (3GPP) UMTS is first specified in release 8 of the 3GPP
specification, and covers the emerging needs of “mobile broadband” into the next decade
with cell data rates of over 300 Mbps expected when the system is fully functional.
The majority of work to date on LTE has focused on the frequency division duplex (LTE
FDD) variant. Following the integration of the Chinese TD-SCDMA standard, based on
time division duplex (TDD), into the 3GPP specifications for LTE, chipset and device
designers are now working to include TDD capability. Now known as TD-LTE, the
standard allows carriers to make use of the unpaired spectrum that many of them already
own.


Compared to previous standards such as GSM/EDGE and W-CDMA, the timescale from
first-generation standards documents to commercial release for LTE in general is short,
and for TD-LTE in particular is shorter, due to its later addition into the standards. For
handsets and data cards, LTE’s maximum specified RF bandwidth of 20 MHz has driven
a change in block diagram and the emergence of standard connections, while the
requirement for multi-format devices which include compatibility with legacy systems
may lead designers to the increased use of software-defined radios. New designs need
more analog/digital cross-domain measurement and "digital-in, RF-out", meaning
designers need new tools and measurement methods.
TD-LTE is specified to operate in the frequency range 1850 to 2620 MHz, and uses the
same MIMO scenarios and up- and down-link modulation formats as FDD: OFDMA
(orthogonal frequency division multiple access) in the downlink and SC-FDMA (single
carrier frequency division multiple access) in the uplink.

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GSM & CDMA Questions

Objective Type Questions

All Questions carry 1 mark

1.      _______ is an analog cellular phone system using FDMA.

a.      AMPS

b.      D-AMPS

c.       GSM

d.      None of the above

2.      ________ is a second-generation cellular phone system based on CDMA and DSSS.

a.      GSM

b.      D-AMPS

c.       IS-95

d.      WCDMA

3.      If you have 5 MHz frequency band what will be the maximum number of channels as per GSM system?

a.      25

b.      35

c.       20

d.      24

4.      Which channel is used to transmit random access signals?

a.      BCCH

b.      CCCH

c.       SDCCH

d.      TCH

5.      The Value Range of Timing Advance (TA) in GSM is?

a.      0-31

b.      0-128

c.       0-61

d.      0-63

6.      In GSM carrier separation is 200KHz whereas in CDMA it is 5MHz (True/False)

7.      When MS is in dedicated mode, the information for non urgent procedure like radio link supervision measurement, transmit power control and timing advance data, is carried on

a.      SDCCH

b.      FACCH

c.       TCH

d.      SACCH

8.      Ciphering key Kc is never transmitted over radio interface. True/ False

9.      Larger cells are more useful in

a.      Densely populated urban areas

b.      Rural areas

c.       Lightly populated urban areas

d.      Mountainous areas.

10.  In up-link direction ARFCN (Absolute Radio Frequency Carrier Number) of 100 corresponds to frequency of (where 1 = ARFCN = 124)

a.      909.8 MHz

b.      910 MHz

c.       910.2 MHz

d.      910.5 MHz

11.  Cells in one Location Area can be served by different VLR s. True/False

12.  For intra-BSC normal Hand-over (not forced Hand-over) unit responsible for taking a decision that Hand-over is required

a.    BSC

b.    MSC

c.    VLR

d.    HLR

13.  In case inter-MSC Handover, MSC to MSC communication makes use of

a.      MAP-D Interface

b.      MAP-E Interface

c.       MAP-C Interface

d.      A-bis

14.  The maximum data rate supported by GSM system is

a.      4800bps

b.      2100bps

c.       6900bps

d.      7000bps

15.  In GSM the signaling protocol supported BTS and BSC is

a.      LAPD

b.      LAPDm

c.       SS7

d.      MAP

16.  Location Area is an area covered by ______.

a.     BTS

b.    BSC

c.     MSC/VLR

d.    None of the above

17.  Which Modulation Scheme is used in GSM and GPRS

a.      PSK

b.      GMSK

c.       ASK

d.      FSK

18.  What is the output power of BTS

a.      33DBm

b.      43DBm

c.       53DBm

d.      63DBm

19.  In CDMA, the pseudo-random code must have the following property

a.      It must be deterministic

b.      It must appear random to a listener without prior knowledge of the code

c.       The code must have a long period

d.      All of the above

20.  In IS-95, two types of Maximum-Length PN Sequences or PN Codes are used: The Short PN Code and the Long PN Code. What is the maximum length of the Short PN Sequence when the PN Code is generated with a 15-stage Linear Shift Register?

a.      16,384 chips

b.      32,768 chips

c.       1,228,800 chips

d.      None of the above