Design of Receiving Wireless Network for the Application on Recovery of Rocket-Borne Memory

Qiu Lin Tan; Xian Sheng Zhang; Li Qiong Ding; Kang Hao; Wen Yi Liu

doi:10.4028/www.scientific.net/AMM.401-403.1845

Paper Titles

Decay Analysis of a 5kW PEMFC Stack in Sightseeing Bus
p.1826

Design and Implementation of Human Resource Management Information System Based on Visual C++
p.1830

Design of 3D-TV Horizontal Parallax Obtaining System Based on FPGA
p.1834

Design of Hot Issue Founding System Based on Tibetan Web
p.1839

Design of Receiving Wireless Network for the Application on Recovery of Rocket-Borne Memory
p.1845

Electric System Security Programming Based on Fuzzy Set
p.1851

Equipment MTTR Demonstration Method Based on Virtual Simulation
p.1855

Evaluation of Parallel Algorithms of Traffic Volume Statistics per Cell in Cellular Network Based on MapReduce Programming Model
p.1859

Formal Analysis of an Efficient Handover Authentication Scheme for EAP-Based Wireless Networks with Extending BAN Logic
p.1864

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 401-403Design of Receiving Wireless Network for the...

Design of Receiving Wireless Network for the Application on Recovery of Rocket-Borne Memory

Abstract:

This paper presents a rocket recovery system logger program. The equipment mainly used in the recycling system of the missile-borne solid state memory. As the signal transmitter, the Beacon is set under the memory of the rocket, sending GPS information real-time when the memory falls down to the ground. For the ground recovery system, we can dispose the specific location of each node based on the topography by calculating the landing area of the beacon. A beacon transponder is placed on each node and each beacon transponder of the node can better receive signal and transmit it to the control center correctly. Every beacon transponder has only one corresponding MAC address, so the control center can distinguish which one is sending signal. This paper designs the framework of the network nodes and the transmission of the physical model, it also analysis the signal transmission system problems such as the high dynamic Doppler effect, the theoretical analysis and experimental verification. The experiment demonstrates that the network node is a particular promising approach in wireless transmission technologies.

You might also be interested in these eBooks

Frontiers of Manufacturing Science and Measuring Technology III

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 401-403)

Pages:

1845-1850

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.401-403.1845

Citation:

Cite this paper

Online since:

September 2013

Authors:

Qiu Lin Tan, Xian Sheng Zhang, Li Qiong Ding, Kang Hao, Wen Yi Liu

Keywords:

Doppler Effect, Frequency-Hopping, Missile Memory, Network Node, Wireless Network

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Yongfeng Ren, Xiaohua Liu, Wenqiang Xu & Wendong Zhang, Xulti-Channel Data Compression, IEEE A&E SYSTEMS MAGAZINE, SEPTEMBER 2008 14-21.

Google Scholar

[2] JAN STEPANEK, MD, and DAVIDW CLAYPOOL MD, GPS signal reception under snow cover: A pilotstudy establishing the potentialusefulness of GPSin avalanche search and rescue operations. Wilderness and EnvironmentalMedicine, 8, 101-104 (1997).

DOI: 10.1580/1080-6032(1997)008[0101:gsrusc]2.3.co;2

Google Scholar

[3] S.J. Prinsenberg, G.A. Fowler, A. van der Baaren, Pack ice convergence measurements by GPS–ARGOS ice beacons. Cold Regions Science and Technology 28 1998 59–72.

DOI: 10.1016/s0165-232x(98)00013-5

Google Scholar

[4] H. Li, E. Chan, G. Chen, AEETC-adaptive energy-efficient timing control in wireless networks with network coding. telecommun syst (2010)45: 289-301.

DOI: 10.1007/s11235-009-9272-8

Google Scholar

[5] Ken Harima, Hirobumi Saiti, Takuji Ebinuma, Navigation message demodulation for GPS receiver on-board spinning rockets, GPS Solut(2012) 16: 495-505.

DOI: 10.1007/s10291-011-0250-8

Google Scholar

[6] Patrick J. FELL, A COMPARATIVE ANALYSIS OF GPS RANGE, DOPPLER AND INTERFEROMETRIC OBSERVATIONS FOR GEODETIC POSITIONING, Naval Surface Weapons Center, Code K-12 Dahlgren, Virginia22448.

Google Scholar

[7] Clement Ogaja, Chalermchon Satirapod, Analysis of high-frequency multipath in 1-Hz GPS kinematic solutions, GPS Solut (2007) 11: 269–280.

DOI: 10.1007/s10291-007-0058-8

Google Scholar

[8] Qi Wang, The linear span of the frequency hopping sequences in optimal sets. Des. Codes Cryptogr . (2011)61: 331-344.

DOI: 10.1007/s10623-010-9480-y

Google Scholar

[9] Wenping Ma, Shaohui Sun, New designs of frequency hopping sequences with low hit zone. Des. Codes Crypyogr. (2011)60: 145-153.

DOI: 10.1007/s10623-010-9422-8

Google Scholar

[10] KIHONG KIM AND GORDON L. STUBER, Interference Mitigation in Asynchronous Slow Frequency Hopping Bluetooth Networks. Wireless Personal Communications 28: 143-159, (2004).

DOI: 10.1109/wpmc.2002.1088160

Google Scholar

[11] JEAN-MARIE BOURJOLLY and SOUHEYL TOUHAMI, Optimizing Frequency Hopping in GSM Cellular Phone Networks. Telecommunication Systems 21: 2-4, 249-260, (2002).

Google Scholar

[12] Wenli Ren, Fang-Wei Fu, Zhengchun Zhou, New sets of frequency-hopping sequences with optimal Hamming correlation. Des. Codes C ryptogr. DOI 10. 1007/s10623-012-9774-3.

DOI: 10.1007/s10623-012-9774-3

Google Scholar