Kloepper Laura N, Smith Adam B, Nachtigall Paul E, Buck John R, Simmons James A, Pacini Aude F
Department of Neuroscience, Brown University, Providence, Rhode Island, United States of America; Electrical and Computer Engineering, University of Massachusetts Dartmouth, Dartmouth, Massachusetts, United States of America.
Department of Zoology, University of Hawaii, Honolulu, Hawaii, United States of America.
PLoS One. 2014 Aug 25;9(8):e105938. doi: 10.1371/journal.pone.0105938. eCollection 2014.
Echolocating animals adjust the transmit intensity and receive sensitivity of their sonar in order to regulate the sensation level of their echoes; this process is often termed automatic gain control. Gain control is considered not to be under the animal's cognitive control, but previous investigations studied animals ensonifying targets or hydrophone arrays at predictable distances. To test whether animals maintain gain control at a fixed level in uncertain conditions, we measured changes in signal intensity for a bottlenose dolphin (Tursiops truncatus) detecting a target at three target distances (2.5, 4 and 7 m) in two types of sessions: predictable and unpredictable. Predictable sessions presented the target at a constant distance; unpredictable sessions moved the target randomly between the three target positions. In the predictable sessions the dolphin demonstrated intensity distance compensation, increasing the emitted click intensity as the target distance increased. Additionally, as trials within sessions progressed, the animal adjusted its click intensity even from the first click in a click train, which is consistent with the animal expecting a target at a certain range. In the unpredictable sessions there was no significant difference of intensity with target distance until after the 7th click in a click train. Together, these results demonstrate that the bottlenose dolphin uses learning and expectation for sonar gain control.
回声定位动物会调整其声纳的发射强度和接收灵敏度,以调节回声的感觉水平;这个过程通常被称为自动增益控制。增益控制被认为不受动物认知控制,但之前的研究是在可预测距离下让动物对目标或水听器阵列发出声纳信号。为了测试动物在不确定条件下是否能将增益控制维持在固定水平,我们在两种类型的实验中,测量了宽吻海豚(宽吻海豚)在三个目标距离(2.5米、4米和7米)探测目标时信号强度的变化:可预测的和不可预测的。可预测实验中目标处于恒定距离;不可预测实验中目标在三个目标位置之间随机移动。在可预测实验中,海豚表现出强度距离补偿,随着目标距离增加而增加发出的滴答声强度。此外,随着实验中的试验进行,动物甚至从一连串滴答声中的第一声就调整其滴答声强度,这与动物预期在一定范围内有目标是一致的。在不可预测实验中,直到一连串滴答声中的第7声之后,强度与目标距离才没有显著差异。总之,这些结果表明宽吻海豚利用学习和预期来进行声纳增益控制。
