Titlebook: Insect Hearing and Acoustic Communication; Berthold Hedwig Book 2014 Springer-Verlag Berlin Heidelberg 2014 Biophysics.Hearing organs.Neur

nephritis

Sound Communication in , ,ation, and amplification in the fruit fly’s ear have been uncovered, and auditory relevant molecules have emerged from mutant screens. This chapter summarized the current state of research on . sound communication and hearing and discusses recent progress in the field.

Keratectomy

后天习得

交响乐

Dorsal

Evolutionary and Phylogenetic Origins of Tympanal Hearing Organs in Insects,framework to reconstruct the ancestral sensory situation in different taxa, and the series of morphological changes during the evolution of an ear. The importance of sensory and neuroanatomical data is discussed for either mapping onto a phylogeny or as characters for phylogenetic analysis.

树胶

Hearing and Sensory Ecology of Acoustic Communication in Bladder Grasshoppers,sensitivity is mediated by an array of six pairs of atympanate ears in abdominal segments A1–A6. The auditory organ, a pleural chordotonal organ, in A1 comprises about 2,000 sensilla, whereas ears in segments A2–A6 are less developed, making pneumorids a unique system for studying the evolution of complex ears from simple precursors.

Lime石灰

Acoustic Communication in the Nocturnal Lepidoptera,bat echolocation signals—may have evolved toward positive responses to male song remains unclear. Analyses of various species offer some insight to this improbable transition, and to the general process by which signals may evolve via the sensory bias mechanism.

捐助

有花

Neural Processing in the Bush-Cricket Auditory Pathway,s for processing intraspecific communication signals. Other neurons are well suited for bat detection and in one neuron auditory stream segregation of conspecific and bat calls was demonstrated. Auditory brain neurons reveal processing properties not encountered in thoracic ganglia.

漂泊

Evolution of Call Patterns and Pattern Recognition Mechanisms in , Katydids,ales are leading the evolutionary divergence of call patterns in this genus. We propose a hypothetical scenario in which genetic bottlenecks and founder effects arising from the climatic history of North America contributed to the rapid diversification of calls in this genus.