Whistling in the Dark: an Acoustic Study of Little Spotted Kiwi

<p>Song function and evolution are two central topics of avian bioacoustic research. Discerning why birds sing and why they have such diversity of song can yield rich information on behaviour and speciation, and can provide important tools for conservation. Knowledge of vocal behaviour of a wide range of bird groups is necessary, yet avian bioacoustic studies have been hampered by a bias towards male song birds, with many species and even whole groups relatively unstudied. The New Zealand kiwi (Apterygidae) are vocal and threatened taxa, and calls play an important part in their conservation. Yet kiwi acoustic behaviour is poorly understood, and although the five species differ significantly in their ecology, only one has been subject to detailed acoustic study. This thesis addresses this gap in knowledge of kiwi ecology with the first acoustic study of the little spotted kiwi (LSK). The principal aims are to improve understanding of kiwi calling behaviour, and to provide further acoustic tools for kiwi conservation. On a broader scale, enhanced knowledge of the acoustic ecology of the taxonomically and ecologically distinct kiwi will provide insight into song function and signal evolution in all birds. Sexual call dimorphism in LSK is shown to be unrelated to size differences, and instead has likely functional significance, with male calls more suited for territorial defence. There is striking ‘acoustic cooperation’ between the sexes which constrains the function of duets in LSK. Analysis of complex vocal features, the first in any ratite, reveals that two-voicing is unexpectedly rare in this species, but that non-linear phenomena are common. Their association with territorial calls and high frequencies indicates that these features provide acoustic emphasis to enhance resource defence or convey aggression or fitness information. Non-linear phenomena are very common in nestling LSK calls, in accordance with the hypothesis that they add unpredictability to prevent habituation. LSK have surprisingly low inter-individual call variability, suggesting that this species may not use calls for individual identification. This lack of variability may be a result of the low genetic diversity in this species. A long-term dataset reveals significant fluctuations in calling rates with temporal and environmental factors. These trends indicate that calls serve an important function for reproduction and pair contact, and that calls may reflect foraging activity. They also provide evidence that kiwi are adversely affected by light pollution. A comparison of automated acoustic methods with manual call counts shows that while they have a different biases, autonomous techniques are highly effective for kiwi conservation monitoring. Microphone array methods have great potential for enhancing conservation and behavioural information through spatial monitoring of kiwi, but are demonstrated not to be suitable with currently available equipment.</p>

Whistling in the Dark: an Acoustic Study of Little Spotted Kiwi

<p>Song function and evolution are two central topics of avian bioacoustic research. Discerning why birds sing and why they have such diversity of song can yield rich information on behaviour and speciation, and can provide important tools for conservation. Knowledge of vocal behaviour of a wide range of bird groups is necessary, yet avian bioacoustic studies have been hampered by a bias towards male song birds, with many species and even whole groups relatively unstudied. The New Zealand kiwi (Apterygidae) are vocal and threatened taxa, and calls play an important part in their conservation. Yet kiwi acoustic behaviour is poorly understood, and although the five species differ significantly in their ecology, only one has been subject to detailed acoustic study. This thesis addresses this gap in knowledge of kiwi ecology with the first acoustic study of the little spotted kiwi (LSK). The principal aims are to improve understanding of kiwi calling behaviour, and to provide further acoustic tools for kiwi conservation. On a broader scale, enhanced knowledge of the acoustic ecology of the taxonomically and ecologically distinct kiwi will provide insight into song function and signal evolution in all birds. Sexual call dimorphism in LSK is shown to be unrelated to size differences, and instead has likely functional significance, with male calls more suited for territorial defence. There is striking ‘acoustic cooperation’ between the sexes which constrains the function of duets in LSK. Analysis of complex vocal features, the first in any ratite, reveals that two-voicing is unexpectedly rare in this species, but that non-linear phenomena are common. Their association with territorial calls and high frequencies indicates that these features provide acoustic emphasis to enhance resource defence or convey aggression or fitness information. Non-linear phenomena are very common in nestling LSK calls, in accordance with the hypothesis that they add unpredictability to prevent habituation. LSK have surprisingly low inter-individual call variability, suggesting that this species may not use calls for individual identification. This lack of variability may be a result of the low genetic diversity in this species. A long-term dataset reveals significant fluctuations in calling rates with temporal and environmental factors. These trends indicate that calls serve an important function for reproduction and pair contact, and that calls may reflect foraging activity. They also provide evidence that kiwi are adversely affected by light pollution. A comparison of automated acoustic methods with manual call counts shows that while they have a different biases, autonomous techniques are highly effective for kiwi conservation monitoring. Microphone array methods have great potential for enhancing conservation and behavioural information through spatial monitoring of kiwi, but are demonstrated not to be suitable with currently available equipment.</p>

Bats (Plecotus auritus) use contact calls for communication among roost mates

Communication between group members is mediated by a diverse range of signals. Contact calls are produced by many species of birds and mammals to maintain group cohesion and associations among individuals. Contact calls in bats are typically relatively low-frequency social calls, produced only for communication. However, echolocation calls (higher in frequency and used primarily for orientation and prey detection) can also facilitate interaction among individuals and location of conspecifics in the roost. We studied calling behaviour of brown long-eared bats (Plecotus auritus) during return to maternity roosts in response to playbacks of social and echolocation calls. We hypothesised that calling by conspecifics would elicit responses in colony members. Bat responses (inspection flights and social calls production) were significantly highest during social call and echolocation call playbacks than during noise (control) playbacks. We suggest that social calling in maternity roosts of brown long-eared bat evolved to maintain associations among roostmates, rather than to find roosts or roostmates, because this species is strongly faithful to roosts and the social groups and roosts are stable over time and space. Living in a stable social group requires recognition of group members and affiliation of social bonds with group members, features that may be mediated by vocal signals.

Vocal communication in wild chimpanzees: a call rate study

Background Patterns of vocal communication have implications for species conservation: a change in calling behaviour can, for instance, reflect a disturbed habitat. More importantly, call rate is a parameter that allows conservation planners to convert call density into animal density, when detecting calls with a passive acoustic monitoring system (PAM). Methods We investigated chimpanzee (Pan troglodytes schweinfurthii) call rate during the late dry season in the Issa Valley, western Tanzania by conducting focal follows. We examined the socio-ecological factors that influence call production rate of savanna woodland chimpanzees. Results We found that sex, proportion of time spent in a vegetation type, proportion of time spent travelling, time of the day, party size and swollen parous female presence had a significant effect on the call rate. Call rate differed among the different demographic classes with subadult and adult males vocalising twice as often as the subadult and adult females and three times as often as the juveniles. Applications The use of PAM and recent statistical developments to estimate animal density is promising but relies on our knowing individual call rate, often not available for many species. With the improvement in automatic call detection, we anticipate that PAM will increasingly be broadly applied to primates but also across taxa, for conservation.

Lesser spot-nosed monkeys coordinate alarm call production with associated Campbell’s monkeys

Forest monkeys often form semi-permanent mixed-species associations to increase group-size related anti-predator benefits without corresponding increases in resource competition. In this study, we analysed the alarm call system of lesser spot-nosed monkeys, a primate that spends most of its time in mixed-species groups while occupying the lowest and presumably most dangerous part of the forest canopy. In contrast to other primate species, we found no evidence for predator-specific alarm calls. Instead, males gave one general alarm call type (‘kroo’) to three main dangers (i.e., crowned eagles, leopards and falling trees) and a second call type (‘tcha-kow’) as a coordinated response to calls produced in non-predatory contexts (‘boom’) by associated male Campbell’s monkeys. Production of ‘kroo’ calls was also strongly affected by the alarm calling behaviour of male Campbell’s monkeys, suggesting that male lesser spot-nosed monkeys adjust their alarm call production to another species’ vocal behaviour. We discuss different hypotheses for this unusual phenomenon and propose that high predation pressure can lead to reliance on other species vocal behaviour to minimise predation. Significance statement Predation can lead to the evolution of acoustically distinct, predator-specific alarm calls. However, there are occasional reports of species lacking such abilities, despite diverse predation pressure, suggesting that evolutionary mechanisms are more complex. We conducted field experiments to systematically describe the alarm calling behaviour of lesser spot-nosed monkeys, an arboreal primate living in the lower forest strata where pressure from different predators is high. We found evidence for two acoustically distinct calls but, contrary to other primates in the same habitat, no evidence for predator-specific alarms. Instead, callers produced one alarm call type (‘kroo’) to all predator classes and another call type (‘tcha-kow’) to non-predatory dangers, but only as a response to a specific vocalisation of Campbell’s monkeys (‘boom’). The production of both calls was affected by the calling behaviour of Campbell’s monkeys, suggesting that lesser spot-nosed monkey vocal behaviour is dependent on the antipredator behaviour of other species. Our study advances the theory of interspecies interactions and evolution of alarm calls.

Acoustic and visual adaptations to predation risk: A predator affects communication in vocal female fish

Predation is an important ecological constraint that influences communication in animals. Fish respond to predators by adjusting their visual signalling behaviour, but the responses in calling behaviour in the presence of a visually detected predator are largely unknown. We hypothesize that fish will reduce visual and acoustic signalling including sound levels and avoid escalating fights in the presence of a predator. To test this we investigated dyadic contests in female croaking gouramis (Trichopsis vittata, Osphronemidae) in the presence and absence of a predator (Astronotus ocellatus, Cichlidae) in an adjoining tank. Agonistic behaviour in T. vittata consists of lateral (visual) displays, antiparallel circling and production of croaking sounds and may escalate to frontal displays. We analysed the number and duration of lateral display bouts, the number, duration, sound pressure level and dominant frequency of croaking sounds as well as contest outcomes. The number and duration of lateral displays decreased significantly in predator as compared to no-predator trials. Total number of sounds per contest dropped in parallel but no significant changes were observed in sound characteristics. In the presence of a predator dyadic contests were decided or terminated during lateral displays and never escalated to frontal displays. The gouramis showed approaching behaviour towards the predator between lateral displays. This is the first study supporting the hypothesis that predators reduce visual and acoustic signalling in a vocal fish. Sound properties, in contrast, did not change. Decreased signalling and the lack of escalating contests reduce the fish’s conspicuousness and thus predation threat.

Male Carollia perspicillata bats call more than females in a distressful context

Distress calls are a vocalization type widespread across the animal kingdom, emitted when the animals are under duress, e.g. when captured by a predator. Here, we report on an observation we came across serendipitously while recording distress calls from the bat species Carollia perspicillata , i.e. the existence of sex difference in the distress calling behaviour of this species. We show that in C. perspicillata bats, males are more likely to produce distress vocalizations than females when hand-held. Male bats call more, their calls are louder, harsher (faster amplitude modulated) and cover lower carrier frequencies than female vocalizations. We discuss our results within a framework of potential hormonal, neurobiological and behavioural differences that could explain our findings, and open multiple paths to continue the study of sex-related differences in vocal behaviour in bats.

Investigating the species-specific association between anuran calling phenology and air temperature

Climate change has been associated in phenological shifts for a variety of taxa. Amphibians, specifically the order Anura (frogs and toads), are considered particularly vulnerable due to their sensitivity to anthropogenic and environmental change. Previous research has documented shifts in the timing of anuran breeding that can be attributed, in part, to climate change, with potential implications for reproduction, survival, and development. This study aims to investigate how air temperature is associated with anuran calling phenology. I will examine the temporal trends in spring and summer air temperature in a lake in northern Ontario, Canada. and quantify seasonal patterns of calling anuran species using acoustic monitoring over a four-month period. I predict that there will be interspecific variation in peak calling associated with air temperature. Additionally, I expect to find asymmetrical association between air temperature and anuran species’ calling behaviour – wherein prolonged breeding species will have a larger optimal temperature range for calling compared to explosive breeding species. The findings of this research will aid in future conservation and provide insight for management strategies of anurans in Canada in response to anticipated climate warming.

Internal migration and mobile communication patterns among pairs with strong ties

Using large-scale call detail records of anonymised mobile phone service subscribers with demographic and location information, we investigate how a long-distance residential move within the country affects the mobile communication patterns between an ego who moved and a frequently called alter who did not move. By using clustering methods in analysing the call frequency time series, we find that such ego-alter pairs are grouped into two clusters, those with the call frequency increasing and those with the call frequency decreasing after the move of the ego. This indicates that such residential moves are correlated with a change in the communication pattern soon after moving. We find that the pre-move calling behaviour is a relevant predictor for the post-move calling behaviour. While demographic and location information can help in predicting whether the call frequency will rise or decay, they are not relevant in predicting the actual call frequency volume. We also note that at four months after the move, most of these close pairs maintain contact, even if the call frequency is decreased.