Constraints and parameters for the system design » History » Version 5
GAY, Adrien, 03/23/2015 10:21 AM
1 | 1 | GAY, Adrien | h1. Constraints and parameters for the system design |
---|---|---|---|
2 | 1 | GAY, Adrien | |
3 | 2 | AUGER, Anne sophie | * Required bit rate |
4 | 2 | AUGER, Anne sophie | |
5 | 2 | AUGER, Anne sophie | In order to define the bit rate required for the transmission of video streams we need some input parameters, provided in the mission statement: |
6 | 3 | AUGER, Anne sophie | |
7 | 3 | AUGER, Anne sophie | > # aspect ratio of the video : AR=1,78 |
8 | 3 | AUGER, Anne sophie | > # quality of the encoded video L=720p |
9 | 3 | AUGER, Anne sophie | > # frame cadence FPS=12 fps |
10 | 2 | AUGER, Anne sophie | |
11 | 2 | AUGER, Anne sophie | We used the following formula |
12 | 2 | AUGER, Anne sophie | |
13 | 2 | AUGER, Anne sophie | p=. Bit rate = FPS*5,0692 * L ^1,391^ /(1000*AR) |
14 | 2 | AUGER, Anne sophie | |
15 | 2 | AUGER, Anne sophie | So |
16 | 2 | AUGER, Anne sophie | |
17 | 2 | AUGER, Anne sophie | p=. *Bit rate=322 Kbps* |
18 | 2 | AUGER, Anne sophie | |
19 | 2 | AUGER, Anne sophie | As the link will allow video transmission, we will need an adapted encapsulation protocol, so we must take into account extra bits: we decide to define a bit rate of 500 kbps. |
20 | 2 | AUGER, Anne sophie | |
21 | 2 | AUGER, Anne sophie | |
22 | 2 | AUGER, Anne sophie | |
23 | 1 | GAY, Adrien | # Network constraints |
24 | 1 | GAY, Adrien | |
25 | 1 | GAY, Adrien | > * Frame format |
26 | 1 | GAY, Adrien | |
27 | 1 | GAY, Adrien | The application foreseen aims at transmitting multimedia content (video on the downlink), so we choose to use the MPEG-4 coding standard. The associated frame format MP4 is particularly adapted for the encapsulation of multimedia data type. |
28 | 1 | GAY, Adrien | |
29 | 1 | GAY, Adrien | > * Protocol stack |
30 | 1 | GAY, Adrien | |
31 | 1 | GAY, Adrien | # Antenna choice |
32 | 1 | GAY, Adrien | |
33 | 1 | GAY, Adrien | > * On board antenna |
34 | 1 | GAY, Adrien | The antenna placed on the aircraft must be compliant with the flight constraints listed in the introduction. Indeed, we should maintain the communication link while the aircraft is performing a turn ( +/- 15° attitude), landing or taking off ( +/- 45° inclination). Therefore, he position of the antenna must be carefully determined in order to be at LOS. |
35 | 1 | GAY, Adrien | |
36 | 1 | GAY, Adrien | Another constraint is the embedded |
37 | 1 | GAY, Adrien | |
38 | 1 | GAY, Adrien | > * Ground station antenna |
39 | 4 | GAY, Adrien | |
40 | 4 | GAY, Adrien | |
41 | 4 | GAY, Adrien | h2. Constraints for the physical layer and RF equipment: |
42 | 4 | GAY, Adrien | |
43 | 4 | GAY, Adrien | |
44 | 4 | GAY, Adrien | (calcul Rb) |
45 | 4 | GAY, Adrien | |
46 | 4 | GAY, Adrien | |
47 | 4 | GAY, Adrien | From the given allocated frequency band, the following parameters are defined: |
48 | 4 | GAY, Adrien | • f : Central frequency of the emitted signal |
49 | 4 | GAY, Adrien | • B: Larger of the allocated bandwidth |
50 | 4 | GAY, Adrien | • EIRP: Maximum power that can be emitted in a given direction |
51 | 4 | GAY, Adrien | |
52 | 4 | GAY, Adrien | From the specifications, the following parameters are defined: |
53 | 4 | GAY, Adrien | • Rb: Useful bit rate of the transmission |
54 | 4 | GAY, Adrien | • R : Minimal distance for the transmission |
55 | 4 | GAY, Adrien | |
56 | 4 | GAY, Adrien | The value of these parameters constrain the parameters of the physical layer and the RF equipment for the design of the system. |
57 | 4 | GAY, Adrien | |
58 | 4 | GAY, Adrien | |
59 | 4 | GAY, Adrien | h3. Physical layer: |
60 | 4 | GAY, Adrien | |
61 | 4 | GAY, Adrien | The study of the physical layer will be limited to the choice of the modulation, the coding and the shaping filter. We will consider a SRRC filter (Square Root Raised Cosine) for the shaping filter as it is commonly used in telecommunication systems for its good performances. |
62 | 4 | GAY, Adrien | |
63 | 4 | GAY, Adrien | Then, the parameters of the physical layer are: |
64 | 4 | GAY, Adrien | • M : Modulation (M=4 : QPSK, M=8 : 8PSK etc) |
65 | 4 | GAY, Adrien | • rho : Coding rate (rho <1) |
66 | 4 | GAY, Adrien | • alpha : roll-off of the SRRC filter |
67 | 4 | GAY, Adrien | |
68 | 4 | GAY, Adrien | In fact all these parameters are linked through the spectral efficiency T of the system, which is fixed by B and Rb: |
69 | 4 | GAY, Adrien | |
70 | 4 | GAY, Adrien | T= cst et T= |
71 | 4 | GAY, Adrien | |
72 | 4 | GAY, Adrien | Then, the parameters of the physical have to comply with the following relation: |
73 | 4 | GAY, Adrien | |
74 | 4 | GAY, Adrien | T>cst |
75 | 4 | GAY, Adrien | |
76 | 4 | GAY, Adrien | |
77 | 4 | GAY, Adrien | |
78 | 4 | GAY, Adrien | h3. Link budget: |
79 | 4 | GAY, Adrien | |
80 | 4 | GAY, Adrien | Here is the expression of the link budget: |
81 | 4 | GAY, Adrien | |
82 | 4 | GAY, Adrien | (link budget) |
83 | 4 | GAY, Adrien | |
84 | 4 | GAY, Adrien | We can notice that all the parameters are already known, except: |
85 | 5 | GAY, Adrien | * (G/T): Figure of merit of the receiver (ISAE antenna) |
86 | 5 | GAY, Adrien | * Lmarg: Margin on the link budget to take into account all the perturbations (antenna |
87 | 4 | GAY, Adrien | depointing, atmosphere attenuation, interferences, non-ideal demodulator …) |
88 | 4 | GAY, Adrien | |
89 | 4 | GAY, Adrien | Lmarg being only linked to physical parameters, we don’t have any influence on it. Then, it has to be evaluated but it is not really a parameter of the design. |
90 | 4 | GAY, Adrien | |
91 | 4 | GAY, Adrien | Power amplifier |
92 | 4 | GAY, Adrien | |
93 | 4 | GAY, Adrien | |
94 | 4 | GAY, Adrien | h2. Conclusion: |
95 | 4 | GAY, Adrien | |
96 | 4 | GAY, Adrien | From these considerations, our aim will be to: |
97 | 5 | GAY, Adrien | * Choose the modulation and the coding (according to the shaping filter) |
98 | 5 | GAY, Adrien | * Compute the gain of the receiving antenna |
99 | 5 | GAY, Adrien | * Propose some technical solution for the receiving antenna |
100 | 4 | GAY, Adrien | |
101 | 4 | GAY, Adrien | We will also develop tools to visualize the influence of the bandwidth, EIRP, useful bit rate and distance on the system design. |
102 | 4 | GAY, Adrien | |
103 | 4 | GAY, Adrien | The aircraft antenna will be considered able to fulfil the required antenna pattern, but we will not discuss about technical solutions for this antenna, as it can be really tricky. |