Application of insect songs in monitoring population density level of Locusta migratoria migratoria (Orthoptera: Acrididae)
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- 作者:Yinliang Wang (1)
Qiuchen Huang (2)
Xue Zhang (1)
Bingzhong Ren (1)
1. Jilin Key Laboratory of Animal Resource Conservation and Utilization ; School of Life Sciences ; Northeast Normal University ; Renmin St. 5268 ; Changchun ; 130024 ; China
2. School of Physics ; Northeast Normal University ; Renmin St. 5268 ; Changchun ; 130024 ; China - 关键词:Insect song ; Asian migratory locust ; Monitoring system
- 刊名:Zoological Studies
- 出版年:2014
- 出版时间:December 2014
- 年:2014
- 卷:53
- 期:1
- 全文大小:737 KB
- 参考文献:1. Bush, SL, Beckers, OM, Schul, J (2009) A complex mechanism of call recognition in the katydid Neoconocephalus affinis (Orthoptera: Tettigoniidae). J Exp Biol 212: pp. 648-655 CrossRef
2. Ceccato, P, Bell, MA, Blumenthal, MB, Connor, SJ, Dinku, T, Grover-Kopec, EK, Ropelewski, CF, Thomson, MC (2006) Use of remote sensing for monitoring climate variability for integrated early warning systems: applications for human diseases and desert locust management. Paper presented at the geoscience and remote sensing symposium. Columbia University, NewYork
3. Drake, VA, Wang, HK, Harman, IT (2002) Insect monitoring radar: remote and network operation. Comput Electron Agr 35: pp. 77-94 CrossRef
4. Ewing, AW (1989) Arthropod bioacoustic. Neurobiology behaviour. Comstock Publishing Associates, New York
5. Fischer, FP, Schulz, U, Schubert, H, Knapp, P, Schm枚ger, M (1997) Quantitative assessment of grassland quality: acoustic determination of population sizes of orthopteran indicator species. Eco Soc America 7: pp. 909-920
6. Garc铆a, MD, Lorier, E, Clemente, E, Presa, JJ (2003) Sound production in Parapellopedon instabilis (Rehn, 1906) (Orthoptera: Gomphocerinae). Annales de la Socie鈥瞭e entomologique de France (NS) 39: pp. 335-342 CrossRef
7. Greenfield, MD Evolution of acoustic communication in the genus Neoconocephalus: discontinuous songs, synchrony, and heterospecific interactions. In: Bailey, WJ, Rentz, DCF eds. (1990) The Tettigoniidae: biology, systematics and evolution. Springer, Heidelberg, pp. 71-97 CrossRef
8. Heady, SE, Denno, RF (1991) Reproductive isolation in Prokelisia planthoppers (Homoptera: Delphacidae): Acoustic differentiation and hybridization failure. J Insect Conserv 4: pp. 367-390
9. Hemp, C, Kehl, S (2010) Taxonomic changes and new species of the flightless genus Parepistaurus Karsch, 1896 (Orthoptera: Acrididae, Coptacridinae) from mountainous East Africa. J Orthop Res 19: pp. 31-39 CrossRef
10. L贸pez, H, Garc铆a, MD, Clemente, E, Presa, JJ, Orom铆, P (2007) Sound production mechanism in pamphagid grasshoppers (Orthoptera). J Zool 275: pp. 1-8 CrossRef
11. Ma, J, Han, X, Hasibagan, A, Wang, C, Zhang, Y, Tang, J, Xie, Z, Deveson, T (2005) Monitoring East Asian migratory locust plagues using remote sensing data and field investigations. Int J Remote Sens 26: pp. 629-634 CrossRef
12. Montealegre-Z, F, Morris, GK (2004) The spiny devil katydids, Panacanthus Walker (Orthoptera: Tettigoniidae): an evolutionary study of acoustic behaviour and morphological traits. Syst Entomol 29: pp. 21-57 CrossRef
13. Ngo, BV, Ngo, CD (2013) Reproductive activity and advertisement calls of the Asian common toad Duttaphrynus melanostictus (Amphibia, Anura, Bufonidae) from Bach Ma National Park, Vietnam. Zoological Studies 52: pp. 12 CrossRef
14. Pace, F, Benard, F, Glotin, H, Adam, O, White, P (2010) Subunit definition and analysis for humpback whale call classification. Appl Acoust 71: pp. 1107-1112 CrossRef
15. Paillette, M, Bizat, N, Joly, D (1997) Differentiation of dialects and courtship strategies in allopatric populations of Drosophila teissieri. J Insect Physiol 43: pp. 809-814 CrossRef
16. Parkman, JP, Frank, JH, Walker, TJ, Schuster, DJ (1996) Classical biological control of Scapteriscus spp. (Orthoptera: Gryllotalpidae) in Florida. Environ Entomol 25: pp. 1415-1420
17. Ragge, DR, Reynolds, WJ (1998) The songs of the grasshoppers and crickets of Western Europe. Harley Books, Colchester
18. Riede, K (1998) Acoustic monitoring of Orthoptera and its potential for conservation. J Insect Conserv 2: pp. 217-223 CrossRef
19. Schmidt, GH, Stelzer, R (2005) Characterization of male structures, and the stridulatory organs of Pantecphylus cerambycinus (Ensifera: Tettigonioidea: Pseudophyllidae). Entomol Gen 27: pp. 143-154
20. Schul, J (1998) Song recognition by temporal cues in a group of closely related bushcricket species (genus Tettigonia). J Comp Physiol A 183: pp. 401-410 CrossRef
21. Shi, RX, Liu, C, Li, D-M, Xie, B-Y (2003) Application of MODIS_NDVI to monitoring locust pest in Baiyang Shallow Lake. J Nutr Dis 12: pp. 155-160
22. Uvarov, B (1996) Grasshoppers and locusts: a handbook of general acridology, vol 1. Cambridge University Press, London
23. Helversen, D (1972) Gesang des MSnnchens und Lautschema des Weibchens bei der Feldheuschrecke Chorthippus biguttulus L. J Comp Physiol A 81: pp. 381-422 CrossRef
24. Wang, Y, Zhang, J, Li, X, Ren, B (2011) Acoustic and molecular differentiation between macropters and brachypters of Eobiana engelhardti engelhardti (Orthoptera: Tettigonioidea). Zoological Studies 50: pp. 636-644
25. Zhang, DX, Yan, L-N, Ji, Y-J, Hewitt, GM, Huang, Z-S (2009) Unexpected relationships of substructured populations in Chinese Locusta migratoria. BMC Evol Biol 9: pp. 144 CrossRef - 刊物主题:Zoology;
- 出版者:Springer Berlin Heidelberg
- ISSN:1810-522X
文摘
Background The locusts Locusta migratoria migratoria (Orthoptera: Acrididae) is the most destructive agricultural pests worldwide, the population and distribution of L. migratoria migratoria growing rapidly in recent years. It is crucial to find a green, economical way to monitor this insect's population for effective control tactics. In this study, acoustic samples were recorded and analyzed under three different density levels of Asian migratory locust L. migratoria migratoria. Results The results showed that the songs of L. migratoria migratoria had a very stable acoustic feature in time domains; then, we used duration of pulse as a tool for identifying and counting the numbers of pulse to classify the population size. After removing the background noises, an automatic density classification and monitoring system was established based on the backpropagation (BP) neural network. The field sample test showed that the accuracy of the density level recognition reached 96.67%. Conclusions The results indicated that the calling songs of insects could be an effective character to distinguish population density level of locust plagues, and it could be potentially used as a green and environmental protection solution in monitoring the dynamics of locust plagues and other acoustic agriculture pests.