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Modelling of DVB-T2 system using Consistent Channel Frequency MATLAB

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This project aims to implement a DVB-T2 (Digital Video Broadcasting for terrestrial television) system using consistent channel frequency responses. Tthe code is designed to use the same output from a channel model for different transmitter configurations so that consistency of performance results can be obtained. After that the overall project will be modified to repeat an experiment “n” times collecting data so that “x%” confidence intervals can be calculated. Historically, DVB is a project worked by more than 250 companies around Europe at first and now worldwide. DVB-T2 is the world’s most advanced digital terrestrial television (DTT) system, offering more robustness, flexibility and at least 50% more efficiency than any other DTT system. It supports SD, HD, mobile TV, or any combination thereof. The GUI for DVB-T2 parameters selection in MATLAB is shown on the left.

MATLAB Simulations & Results

DVB-T2 is the second generation standard technology used for digital terrestrial TV broadcasting. As it’s a new technology so it has many fields to explore and research, and the best way of researching on any new technology is via simulations. Simulations provide an easy and efficient way to evaluate the performance of any system. For simulation purposes, MATLAB software was chosen in this thesis because of its wide range of tools and ability to show graphical results in a very appropriate form. . Further, this DVB-T2 simulation model could be extended easily to simulate DVB-H, which shares many features with DVB-T2 (only the physical layer that needs modification). The most important feature, I discussed in my simulations are:

• Comparison of Bit Error Rate (BER) and Signal to noise Ratio (SNR).

DVB-T2 scheme can handle wide range of sub carriers from a range of 1k to 32k; these sub carriers can be fixed or mobile. In this thesis, experiments are performed on mobile transmission of signals to 4000 sub carriers. Below are discussed three different mobile scenarios, for different speeds of mobiles user, which are:

• Pedestrian moving at the speed of 0.1 km/h.
• Bus moving at the speed of 5km/h.
• Car moving at the speed of 10 km/h.

In all the scenarios, the factors mentioned below are kept constant so that a real comparison can be obtained and it could be checked that whether the speed affects the signal or not. These constant factors are:

• Transmission Mode is SISO.
• Transmitting Antenna Cross Correlation is 0.5.
• Receiving Antenna Cross Correlation is 0.5.
• Environment considered for these simulations is rural.
• Radio Channel type is Rayleigh with k factor of 1000.
• Carrier frequency is 91.429MHz.

1.1  Initial MATLAB model

During this thesis, help was taken from a MATLAB model of DVB-T2 transmission system designed by a student at Brunel University. First this initial model was studied and then enhanced it to a higher level. The first model designed by the student at Brunel University, performed the iterations on the DVB-T2 system and gives the results for just one cycle. Explanation of this initial model is discussed in detail below.

1.1.1    Explanation of Initial Model

After the user input all the values in the GUI, this model first calculates the below three values depending on the number of subcarriers attached to the DVB-T2 system.

• Useful OFDM period.
• Maximum number of sub carriers.
• IFFT / FFT length.

After getting this information, the model performs the QAM modulation over the signal so that it could be sent from the transmitter to the receiver. Next, depending on the value of Pilot Pattern given by the user, it calculates the scattered Pilot Amplitudes for the system. After that, it calculates the distortion in transmission depending on area in which the signal is propagating.

In order to calculate the distortion, FFT technique is performed on the signals to get their frequency response. As the signal has already sent from the transmitter after QAM modulation so demodulation on the receiver side is necessary. The model performs the same and demodulates the signal and finally it calculates the value of Signal to noise ratio (SNR) and Bit Error Rate (BER). At the end, it simply plots the graphs of SNR and BER for the visual representation.

1.1.2    Results of Initial Model

Different experiments were performed on the initial model and checked its results. The results are given below for three different experiments, which are:

• Speed of mobile = 0.1 km/s , Total Iterations = 5000
• Speed of mobile = 1.0 km/s , Total Iterations = 5000
• Speed of mobile = 10 km/s , Total Iterations = 5000

Results of these experiments are shown in figure 6.1, 6.2 and 6.3 respectively. Table 6.1, 6.2 and 6.3 gives the values of BER and average BER for all the values of SNR. If these three graphs are closely examined then it can be shown that the band limited impulse response increases as the speed increase and so as the BER and SNR.

The reason for such behavior is that because as the speed of the mobile increase, signal distortion also increases and it becomes difficult for the receiver to catch the signal, that’s the main reason that user travelling in high speed vehicle faces more distortion as compared to a pedestrian.

Results of First Experiment (Speed = 0.1km/s, Iterations = 5000)

 

SNR	BER & Average BER
SNR: 0	BER:0.103833
SNR: 0	NoAvrg_BER:0.160358
SNR: 5	BER:0.014366
SNR: 5	NoAvrg_BER:0.033706
SNR: 10	BER:0.000206
SNR: 10	NoAvrg_BER:0.001528
SNR: 15	BER:0.000002
SNR: 15	NoAvrg_BER:0.000107
SNR: 20	BER:0.001543
SNR: 20	NoAvrg_BER:0.002319
SNR: 25	BER:0.000076
SNR: 25	NoAvrg_BER:0.000184
SNR: 30	BER:0.000000
SNR: 30	NoAvrg_BER:0.000164

BER & Average BER Vs. SNR for experiment 1

Results of Second Experiment (Speed = 1km/s, Iterations = 5000)

SNR	BER & Average BER
SNR: 0	BER:0.140855
SNR: 0	NoAvrg_BER:0.195596
SNR:5	BER:0.046527
SNR:5	NoAvrg_BER:0.071364
SNR:10	BER:0.011363
SNR:10	NoAvrg_BER:0.019860
SNR:15	BER:0.003815
SNR:15	NoAvrg_BER:0.006448
SNR:20	BER:0.000604
SNR:20	NoAvrg_BER:0.001222
SNR:25	BER:0.000214
SNR:25	NoAvrg_BER:0.000404
SNR:30	BER:0.000233
SNR:30	NoAvrg_BER:0.000503

BER & Average BER vs. SNR for experiment 2

Results of Third Experiment (Speed = 10km/s, Iterations = 5000)

SNR	BER & Average BER
SNR: 0	BER:0.128177
SNR: 0	NoAvrg_BER:0.182924
SNR:5	BER:0.056198
SNR:5	NoAvrg_BER:0.084254
SNR:10	BER:0.023229
SNR:10	NoAvrg_BER:0.035131
SNR:15	BER:0.006793
SNR:15	NoAvrg_BER:0.010362
SNR:20	BER:0.001748
SNR:20	NoAvrg_BER:0.002801
SNR:25	BER:0.000425
SNR:25	NoAvrg_BER:0.000691
SNR:30	BER:0.000354
SNR:30	NoAvrg_BER:0.000515

BER & Average BER vs. SNR for experiment 3

Although the results given by these simulations were quite accurate but they were not accurate enough to be trusted, as they were performing the process just for one period and getting the results on the basis of that.

Final MATLAB Model after Modifications

The initial MATLAB model is modified in this thesis, in order to use the same output from the channel model with different transmitter configurations to obtain more consistent results that can be compared with each other. Then theDVB-T2model will be modified so that it can be simulated using Matlab n times collecting data so that an x% confidence interval can be measured.

The results obtained after modifications were very consistent as they were performing the whole scenario for N times (defined by the user), this attribute lacks in the initial model as it was performing the complete task just for one cycle of time and any kind of distortion could fluctuate the results. While in modified model, the same process was performed by N times defined by the user and the results obtained are actually the average of all the cycles and hence providing a very consistent output, which couldn’t be distorted by any external factors.

Moreover, this new model further enhanced the initial model to calculate the Mean BER as it will give the overall performance of BER and average BER. Furthermore, calculates the standard BER on the basis of which global BER is also calculated.

As the simulation of DVB-T2 requires a lot of input parameters from the user, that’s why a GUI is also designed in MATLAB, which makes the working of this project user friendly. User can easily change the parameters of the system using that GUI. On startup, the GUI looks like as shown in figure 4.2:

GUI for DVB-T2 parameters selection

As mentioned above, taking all the other parameters constant, three experiments are performed for the mobile user moving at different speeds with different Iterations and no. of repeats, which are:

• Pedestrian moving at the speed of 0.1 km/h, with no of iterations = 500 and N=2.
• Bus moving at the speed of 5km/h, with no of iterations = 200 and N=2.
• Car moving at the speed of 10 km/h, with no of iterations = 1000 and N=2.

1.2.1    Results of First Experiment of Modified Model:

Results of the first experiment are shown in the figure 6.5, 6.6 and 6.7 respectively. While the theoretical values of BER and average BER for the corresponding SNR are shown in table 6.4 and the Mean BER and std BER are shown in table 6.5.

• Value of Global BER for the experiment comes out to be -2.4021.

Results for Experiment 1 (Speed=0.1km/s, Iterations=500, N=2)

Results for Experiment 1 (Speed=0.1km/s, Iterations=500, N=2)

Results for Experiment 1 (Speed=0.1km/s, Iterations=500, N=2)

For N=1		For N=2
SNR: 0	BER:0.131272	SNR: 0	BER:0.131542
SNR: 0	NoAvrg_BER:0.185916	SNR: 0	NoAvrg_BER:0.186218
SNR:1	BER:0.107086	SNR:1	BER:0.106672
SNR:1	NoAvrg_BER:0.157698	SNR:1	NoAvrg_BER:0.157319
SNR:2	BER:0.086805	SNR:2	BER:0.086459
SNR:2	NoAvrg_BER:0.129841	SNR:2	NoAvrg_BER:0.129562
SNR:3	BER:0.087178	SNR:3	BER:0.086924
SNR:3	NoAvrg_BER:0.128066	SNR:3	NoAvrg_BER:0.127755
SNR:4	BER:0.081465	SNR:4	BER:0.081709
SNR:4	NoAvrg_BER:0.116619	SNR:4	NoAvrg_BER:0.116581
SNR:5	BER:0.028071	SNR:5	BER:0.028074
SNR:5	NoAvrg_BER:0.051596	SNR:5	NoAvrg_BER:0.051751
SNR:6	BER:0.016450	SNR:6	BER:0.016439
SNR:6	NoAvrg_BER:0.030762	SNR:6	NoAvrg_BER:0.030725
SNR:7	BER:0.012705	SNR:7	BER:0.012607
SNR:7	NoAvrg_BER:0.022399	SNR:7	NoAvrg_BER:0.022108
SNR:8	BER:0.036446	SNR:8	BER:0.036612
SNR:8	NoAvrg_BER:0.052421	SNR:8	NoAvrg_BER:0.052642
SNR:9	BER:0.026200	SNR:9	BER:0.026378
SNR:9	NoAvrg_BER:0.039987	SNR:9	NoAvrg_BER:0.040434
SNR:10	BER:0.014162	SNR:10	BER:0.014155
SNR:10	NoAvrg_BER:0.023779	SNR:10	NoAvrg_BER:0.023805
SNR:11	BER:0.007526	SNR:11	BER:0.007539
SNR:11	NoAvrg_BER:0.013874	SNR:11	NoAvrg_BER:0.013838
SNR:12	BER:0.015524	SNR:12	BER:0.015382
SNR:12	NoAvrg_BER:0.023693	SNR:12	NoAvrg_BER:0.023602
SNR:13	BER:0.005303	SNR:13	BER:0.005448
SNR:13	NoAvrg_BER:0.008758	SNR:13	NoAvrg_BER:0.008764
SNR:14	BER:0.008712	SNR:14	BER:0.008823
SNR:14	NoAvrg_BER:0.014517	SNR:14	NoAvrg_BER:0.014421
SNR:15	BER:0.013224	SNR:15	BER:0.013144
SNR:15	NoAvrg_BER:0.019547	SNR:15	NoAvrg_BER:0.019305
SNR:16	BER:0.001919	SNR:16	BER:0.001890
SNR:16	NoAvrg_BER:0.003767	SNR:16	NoAvrg_BER:0.003703
SNR:17	BER:0.002873	SNR:17	BER:0.002907
SNR:17	NoAvrg_BER:0.004932	SNR:17	NoAvrg_BER:0.005001
SNR:18	BER:0.000610	SNR:18	BER:0.000641
SNR:18	NoAvrg_BER:0.001197	SNR:18	NoAvrg_BER:0.001243
SNR:19	BER:0.006294	SNR:19	BER:0.006231
SNR:19	NoAvrg_BER:0.009262	SNR:19	NoAvrg_BER:0.009209
SNR:20	BER:0.001799	SNR:20	BER:0.001749
SNR:20	NoAvrg_BER:0.003268	SNR:20	NoAvrg_BER:0.003248
SNR:21	BER:0.000966	SNR:21	BER:0.000998
SNR:21	NoAvrg_BER:0.001677	SNR:21	NoAvrg_BER:0.001636
SNR:22	BER:0.001733	SNR:22	BER:0.001778
SNR:22	NoAvrg_BER:0.002772	SNR:22	NoAvrg_BER:0.002883
SNR:23	BER:0.004920	SNR:23	BER:0.004914
SNR:23	NoAvrg_BER:0.007638	SNR:23	NoAvrg_BER:0.007743
SNR:24	BER:0.000089	SNR:24	BER:0.000098
SNR:24	NoAvrg_BER:0.000220	SNR:24	NoAvrg_BER:0.000234
SNR:25	BER:0.000001	SNR:25	BER:0.000001
SNR:25	NoAvrg_BER:0.000052	SNR:25	NoAvrg_BER:0.000052
SNR:26	BER:0.000408	SNR:26	BER:0.000393
SNR:26	NoAvrg_BER:0.000695	SNR:26	NoAvrg_BER:0.000646
SNR:27	BER:0.000583	SNR:27	BER:0.000600
SNR:27	NoAvrg_BER:0.001222	SNR:27	NoAvrg_BER:0.001242
SNR:28	BER:0.000352	SNR:28	BER:0.000381
SNR:28	NoAvrg_BER:0.000609	SNR:28	NoAvrg_BER:0.000625
SNR:29	BER:0.000107	SNR:29	BER:0.000124
SNR:29	NoAvrg_BER:0.000365	SNR:29	NoAvrg_BER:0.000384
SNR:30	BER:0.000367	SNR:30	BER:0.000351
SNR:30	NoAvrg_BER:0.000720	SNR:30	NoAvrg_BER:0.000695

SNR Vs. BER values for Experiment 1

Mean BER	std BER
-0.8814	0.0006
-0.9711	0.0012
-1.0623	0.0012
-1.0602	0.0009
-1.0884	0.0009
-1.5517	0.0000
-1.7840	0.0002
-1.8977	0.0024
-1.4374	0.0014
-1.5802	0.0021
-1.8490	0.0001
-2.1231	0.0005
-1.8110	0.0028
-2.2696	0.0083
-2.0571	0.0039
-1.8799	0.0019
-2.7203	0.0046
-2.5391	0.0035
-3.2039	0.0151
-2.2033	0.0031
-2.7511	0.0086
-3.0078	0.0099
-2.7556	0.0079
-2.3083	0.0004
-4.0308	0.0285
-6.1938	0
-3.3978	0.0118
-3.2281	0.0086
-3.4365	0.0247
-3.9387	0.0460
-3.4455	0.0137

Mean BER & std BER values for Experiment 1

1.2.2    Results of Second Experiment of Modified Model:

Figure 6.8, 6.9 and 6.10 gives us the results for the experiment 2, when user is travelling at the speed of 1km/s and the no of iterations taken here are 500 with repeat cycle i.e. N=2. Table 6.6 and 6.7 gives us the values of SNR vs. BER and the Mean BER and standard BER respectively.

• Global BER comes out for experiment 2 was –inf.

Results for Experiment 2 (Speed=1km/s, Iterations=500, N=2)

Results for Experiment 2 (Speed=1km/s, Iterations=500, N=2)

Results for Experiment 2 (Speed=1km/s, Iterations=500, N=2)

For N = 1		For N = 2
SNR: 0	BER:0.144963	SNR: 0	BER:0.144537
SNR: 0	NoAvrg_BER:0.200382	SNR: 0	NoAvrg_BER:0.200617
SNR:1	BER:0.103536	SNR:1	BER:0.103496
SNR:1	NoAvrg_BER:0.153318	SNR:1	NoAvrg_BER:0.153312
SNR:2	BER:0.081079	SNR:2	BER:0.081874
SNR:2	NoAvrg_BER:0.123080	SNR:2	NoAvrg_BER:0.123966
SNR:3	BER:0.056279	SNR:3	BER:0.056618
SNR:3	NoAvrg_BER:0.096223	SNR:3	NoAvrg_BER:0.096636
SNR:4	BER:0.070647	SNR:4	BER:0.070241
SNR:4	NoAvrg_BER:0.103436	SNR:4	NoAvrg_BER:0.103023
SNR:5	BER:0.063094	SNR:5	BER:0.063427
SNR:5	NoAvrg_BER:0.089725	SNR:5	NoAvrg_BER:0.090577
SNR:6	BER:0.020785	SNR:6	BER:0.021318
SNR:6	NoAvrg_BER:0.039970	SNR:6	NoAvrg_BER:0.040469
SNR:7	BER:0.024660	SNR:7	BER:0.024455
SNR:7	NoAvrg_BER:0.040979	SNR:7	NoAvrg_BER:0.041170
SNR:8	BER:0.032986	SNR:8	BER:0.032662
SNR:8	NoAvrg_BER:0.052140	SNR:8	NoAvrg_BER:0.052100
SNR:9	BER:0.023306	SNR:9	BER:0.022988
SNR:9	NoAvrg_BER:0.037168	SNR:9	NoAvrg_BER:0.037283
SNR:10	BER:0.009120	SNR:10	BER:0.008878
SNR:10	NoAvrg_BER:0.017749	SNR:10	NoAvrg_BER:0.017499
SNR:11	BER:0.023258	SNR:11	BER:0.023224
SNR:11	NoAvrg_BER:0.034964	SNR:11	NoAvrg_BER:0.034473
SNR:12	BER:0.023534	SNR:12	BER:0.023745
SNR:12	NoAvrg_BER:0.034579	SNR:12	NoAvrg_BER:0.034325
SNR:13	BER:0.000103	SNR:13	BER:0.000101
SNR:13	NoAvrg_BER:0.000588	SNR:13	NoAvrg_BER:0.000648
SNR:14	BER:0.000016	SNR:14	BER:0.000010
SNR:14	NoAvrg_BER:0.000196	SNR:14	NoAvrg_BER:0.000231
SNR:15	BER:0.000009	SNR:15	BER:0.000014
SNR:15	NoAvrg_BER:0.000209	SNR:15	NoAvrg_BER:0.000240
SNR:16	BER:0.001996	SNR:16	BER:0.002008
SNR:16	NoAvrg_BER:0.003367	SNR:16	NoAvrg_BER:0.003535
SNR:17	BER:0.002367	SNR:17	BER:0.002430
SNR:17	NoAvrg_BER:0.003467	SNR:17	NoAvrg_BER:0.003535
SNR:18	BER:0.000002	SNR:18	BER:0.000004
SNR:18	NoAvrg_BER:0.000010	SNR:18	NoAvrg_BER:0.000018
SNR:19	BER:0.001298	SNR:19	BER:0.001367
SNR:19	NoAvrg_BER:0.002071	SNR:19	NoAvrg_BER:0.002116
SNR:20	BER:0.009918	SNR:20	BER:0.009850
SNR:20	NoAvrg_BER:0.014701	SNR:20	NoAvrg_BER:0.014585
SNR:21	BER:0.000472	SNR:21	BER:0.000521
SNR:21	NoAvrg_BER:0.000769	SNR:21	NoAvrg_BER:0.000854
SNR:22	BER:0.001085	SNR:22	BER:0.001169
SNR:22	NoAvrg_BER:0.001855	SNR:22	NoAvrg_BER:0.001917
SNR:23	BER:0.001360	SNR:23	BER:0.001495
SNR:23	NoAvrg_BER:0.002240	SNR:23	NoAvrg_BER:0.002427
SNR:24	BER:0.000595	SNR:24	BER:0.000621
SNR:24	NoAvrg_BER:0.001258	SNR:24	NoAvrg_BER:0.001321
SNR:25	BER:0.000873	SNR:25	BER:0.000820
SNR:25	NoAvrg_BER:0.001457	SNR:25	NoAvrg_BER:0.001422
SNR:26	BER:0.000003	SNR:26	BER:0.000003
SNR:26	NoAvrg_BER:0.000199	SNR:26	NoAvrg_BER:0.000201
SNR:27	BER:0.000326	SNR:27	BER:0.000342
SNR:27	NoAvrg_BER:0.000637	SNR:27	NoAvrg_BER:0.000651
SNR:28	BER:0.000198	SNR:28	BER:0.000216
SNR:28	NoAvrg_BER:0.000270	SNR:28	NoAvrg_BER:0.000262
SNR:29	BER:0.000000	SNR:29	BER:0.000000
SNR:29	NoAvrg_BER:0.000000	SNR:29	NoAvrg_BER:0.000000
SNR:30	BER:0.000000	SNR:30	BER:0.000000
SNR:30	NoAvrg_BER:0.000071	SNR:30	NoAvrg_BER:0.000078

SNR Vs. BER values for Experiment 2

Mean BER	Std BER
0.8394	0.0009
0.9850	0.0001
1.0890	0.0030
1.2483	0.0018
1.1522	0.0018
1.1989	0.0016
1.6767	0.0078
1.6098	0.0026
1.4838	0.0030
1.6355	0.0042
2.0458	0.0083
1.6337	0.0005
1.6264	0.0027
3.9915	0.0072
4.8895	0.1323
4.9486	0.1512
2.6985	0.0018
2.6201	0.0081
5.5089	0.1569
2.8755	0.0159
2.0051	0.0021
3.3048	0.0302
2.9484	0.0231
2.8460	0.0291
3.2160	0.0133
3.0727	0.0192
5.4949	0
3.4765	0.0154
3.6850	0.0273
Inf	NaN
Inf	NaN

Mean BER and std BER values for Experiment 2

Remarks

This thesis presents the design and Implementation of DVB-T2 system in MATLAB software. The basic purpose of this thesis is to check the bit error ratio (BER) and signal to noise ratio (SNR) for DVB-T2 system so that the system could be improved to a better quality. DVB-T2 system is evaluated for mobile users moving at different speeds. It is clearly shown that the mobility has an impact on the received signal, where the SNR goes to zero in some points. This behavior will generate high BER. If the figures for impulse responses are checked for all the three experiments then it is depicted that the Impulse is high for the third experiment where the mobility speed is higher than the first two experiments. The packet data loss is almost zero for the first experiment while it’s increasing in the second and is higher in the third. The number of packet lost confirms this behavior that high losses occurred in the case of high mobility.