A Bioacoustic Record of a Conservancy in the Mount Kenya Ecosystem

Ciira wa Maina; David Muchiri; Peter Njoroge

doi:10.3897/BDJ.4.e9906

Biodiversity Data Journal : Data Paper (Biosciences)

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Data Paper (Biosciences)

A Bioacoustic Record of a Conservancy in the Mount Kenya Ecosystem

Ciira wa Maina^‡, David Muchiri^§, Peter Njoroge^|

‡ Department of Electrical and Electronic Engineering, Dedan Kimathi University of Technology, Nyeri, Kenya

§ Dedan Kimathi University Wildlife Conservancy, Dedan Kimathi University of Technology, Nyeri, Kenya

| Ornithology Section, Department of Zoology, National Museums of Kenya, Nairobi, Kenya

Corresponding author:

Academic editor: Therese Catanach

Received: 17 Jul 2016 | Accepted: 23 Sep 2016 | Published: 05 Oct 2016

This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Citation: wa Maina C, Muchiri D, Njoroge P (2016) A Bioacoustic Record of a Conservancy in the Mount Kenya Ecosystem. Biodiversity Data Journal 4: e9906. https://doi.org/10.3897/BDJ.4.e9906

Abstract

Background

Environmental degradation is a major threat facing ecosystems around the world. In order to determine ecosystems in need of conservation interventions, we must monitor the biodiversity of these ecosystems effectively. Bioacoustic approaches offer a means to monitor ecosystems of interest in a sustainable manner. In this work we show how a bioacoustic record from the Dedan Kimathi University wildlife conservancy, a conservancy in the Mount Kenya ecosystem, was obtained in a cost effective manner. A subset of the dataset was annotated with the identities of bird species present since they serve as useful indicator species. These data reveal the spatial distribution of species within the conservancy and also point to the effects of major highways on bird populations. This dataset will provide data to train automatic species recognition systems for birds found within the Mount Kenya ecosystem. Such systems are necessary if bioacoustic approaches are to be employed at the large scales necessary to influence wildlife conservation measures.

New information

We provide acoustic recordings from the Dedan Kimathi University wildlife conservancy, a conservancy in the Mount Kenya ecosystem, obtained using a low cost acoustic recorder. A total of 2701 minute long recordings are provided including both daytime and nighttime recordings. We present an annotation of a subset of the daytime recordings indicating the bird species present in the recordings. The dataset contains recordings of at least 36 bird species. In addition, the presence of a few nocturnal species within the conservancy is also confirmed.

Keywords

Conservation, Bioacoustics, Indicator taxa, Bird species, Raspberry Pi

Introduction

The world's biodiversity faces a number of threats including human encroachment into wildlife habitats and climate change. With a large number of species under threat, it is important to invest in conservation to ensure that these species are saved. However, due to limited resources it is important to target conservation efforts where they are most needed. To do this, it is important to collect relevant data from various ecosystems so as to determine those that are under threat and also those that have rich biodiversity. Efforts in this direction have led to the identification of biodiversity hotspots aimed at targeting conservation priorities (Myers et al. 2000). While the identification of these hotspots is an important step, conservation cannot be limited to just these regions (Kareiva and Marvier 2003). There is therefore a need to develop effective strategies to monitor a wide range of ecosystems so that conservation efforts can be effectively directed.

Current approaches to biodiversity assessment involve experts conducting surveys in the ecosystems of interest. While this approach is likely to lead to accurate measurement of species richness, it is expensive and cannot scale. Techniques such as rapid biodiversity assessment can be more widely applied because they limit the surveys to indicator taxa (Kerr et al. 2008) but they still require experts to conduct the surveys in the field. To obtain data on species richness at the scale needed to inform conservation efforts, it is necessary to automate the processes of data collection and annotation and develop methods to estimate species richness from these data. One step in this direction is the use of bioacoustic approaches to biodiversity monitoring where the sounds emitted by a wide range of living organisms are used to estimate species richness of the region from which the recordings were obtained (Sueur et al. 2008). Bioacoustic approaches to biodiversity monitoring have received considerable attention. They have been applied to monitor tropical ecosystems (Sueur et al. 2008) and to monitor species of interest including birds (Zwart et al. 2014, Ulloa et al. 2016), bats (Walters et al. 2012) and whales (Sciacca et al. 2015).

Bioacoustic approaches have several advantages over traditional surveys including 1) Acoustic recordings can be archived to serve as a permanent record of the ecosystem at a particular time. 2) Recording equipment can be used for long term monitoring. 3) It is straight forward to survey vocal nocturnal species using acoustic recorders. 4) Expert knowledge on the species of interest is not needed to mount the recorders. Despite these advantages, there are still a number of disadvantages including 1) Acoustic recorders generate a lot of data which are difficult to annotate and can be expensive to store. 2) Species that rarely vocalize will be disregarded in bioacoustic surveys. 3) Recording equipment can be expensive.

In order to increase the use of bioacoustic approaches in tropical ecosystems, it is necessary to address these shortcomings. A number of authors have demonstrated the use of low cost acoustic recorders for biodiversity monitoring (Farina et al. 2014). In addition, there are efforts to develop automatic species recognition systems for bird species which serve as useful indicator species in ecosystems of interest (Briggs et al. 2012, Stowell and Plumbley 2014). It is important for research efforts to demonstrate the utility of acoustic recordings obtained in tropical ecosystems using low cost recorders for biodiversity assessment and to develop methods for automated species recognition based on acoustic recordings.

In this work we present a dataset of acoustic recordings obtained from the Dedan Kimathi University wildlife conservancy in central Kenya. This work is part of the Kenya Bioacoustics Project (https://sites.google.com/site/kenyabioacoustics/) which aims to use bioacoustic approaches for biodiversity monitoring within Kenya. The acoustic recordings in this dataset were obtained using a cheap recorder developed at the university. The recorder is based on the Raspberry Pi, a cheap microprocessor, connected to a cheap USB microphone. A number of recordings in the dataset are annotated by an expert ornithologist (PN, the third author) to indicate the bird species present in each recording and these provide a snap shot of the ecosystem during the duration of the study. This annotated dataset can be used to train automatic species recognition systems for use in other acoustic studies. Such a system has already been developed for the Hartlaub's Turaco (wa Maina 2016).

General description

Project description

Study area description:

The study was conducted at the Dedan Kimathi University Wildlife Conservancy (DeKUWC) located at 0°23'17.0"S, 36°57'43.2"E at an elevation of approximately 1800m (see Fig. 1). The conservancy covers an area of 120 Acres with three ecological zones namely open grassland, undisturbed indigenous forest and aquatic zones due to a permanent river that runs along its Northern boundary. The DeKUWC is located in the central part of Kenya and receives about 1000mm of rainfall annually. This is in two rainy seasons from mid March to May and October to November. There are two dry seasons from December to March and June to September. The conservancy is part of the Mount Kenya ecosystem with the Kabiruini forest bordering it to the North. The Kabiruini forest has suffered from human encroachment with quarrying and cattle grazing occurring within the forest. To the South, the conservancy is bordered by human settlements and a major highway (B5). See the map in Fig. 1 and the photographs in Fig. 2.

Figure 1.

The location of the DeKUWC in central Kenya is shown (a). A map of the DeKUWC with locations of the point counts and acoustic recorders indicated (b).

Figure 2.

A footpath within the DeKUWC (a) and a veiw of DeKUWC and the adjacent Kabiruini forest (b). Point counts were performed along these footpaths. Photographs by CwM

Sampling methods

Sampling description:

Data collected in this study included point count data and acoustic recordings collected using a cheap microphone connected to a Raspberry Pi microprocessor. We (CwM and DM) performed point counts at twenty locations within the Dedan Kimathi University of Technology wildlife conservancy (DeKUWC) on two different days: 5th January, 2016 (10am to 12noon) and 28th January, 2016 (8am to 10am) (ten on each day). The points were separated by approximately 40 meters and birds seen or heard and judged to be within 20m of each location were recorded for ten minutes. Bird species identification was aided by the use of a guide book (Stevenson and Fanshawe 2002).

To collect the audio recordings, we used four acoustic recorders and these were left at locations near some of the point count locations. The recorders were left at ground level. A total of eight locations were sampled, four on each day. The 20 point count locations are labeled A-T and the acoustic recorder locations are labeled 1-8 as shown in Fig. 3. The recorders were left at these points for approximately 28 hours and were programmed to record for one minute at five minute intervals. This produced approximately 340 minute long recordings per site. We set the sampling rate of the recorders to 16kHz at 16 bit resolution. The recordings were saved in the uncompressed WAV format.

Figure 3.

The DeKUWC with locations of the point counts and acoustic recorders indicated. The 20 point count locations are labelled A-T (a) and the acoustic recorder locations are labelled 1-8 (b).

Geographic coverage

Description:

The study was conducted at the Dedan Kimathi University Wildlife Conservancy (DeKUWC) located at 0°23'17.0"S, 36°57'43.2"E at an elevation of approximately 1800m.

Taxonomic coverage

Description:

A total of 54 bird species were recorded during the study. Of these, 33 were recorded during the point counts and 36 identified using recordings of their vocalizations. 15 species were identified during both the point counts and using the audio recordings. The list of birds species identified during the study is shown in Table 1. This table includes a four-letter code used during annotation of the recordings. These codes were generated using the same rules used to generate the four-letter codes for North American birds (Klimkiewicz and Robbins 1978, Pyle and DeSante 2003). Photographs of a few of the birds are shown in Fig. 4.

Table 1.

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Bird species identified during the study.

#	Common Name	Scientific Name	Four-Letter Code
1	Abyssinian Crimsonwing	Cryptospiza salvadorii	ABCR
2	African Dusky Flycatcher	Muscicapa adusta	ADFL
3	African Grey Flycatcher	Melaenornis microrhynchus	AGFL
4	African Paradise Flycatcher	Terpsiphone viridis	APFL
5	Augur Buzzard	Buteo augur	AUBU
6	Black-backed Puffback	Dryoscopus cubla	BBPU
7	Black-collared Apalis	Oreolais pulcher	BCAP
8	Black Cuckoo	Cuculus clamosus	BLCU
9	Black-headed Oriole	Oriolus larvatus	BHOR
10	Black Saw-wing	Psalidoprocne pristoptera	BLSW
11	Black-throated Wattle-eye	Platysteira peltata	BTWE
12	Blue-mantled Crested Flycatcher	Trochocercus cyanomelas	BMCF
13	Brown Woodland Warbler	Phylloscopus umbrovirens	BWWA
14	Cape Robin-Chat	Cossypha caffra	CARC
15	Chinspot Batis	Batis molitor	CHBA
16	Cinnamon-chested Bee-eater	Merops oreobates	CCBE
17	Collared Sunbird	Hedydipna collaris	COSU
18	Common Bulbul	Pycnonotus barbatus	COBU
19	Eastern Double-collared Sunbird	Cinnyris mediocris	EDCS
20	Emerald-spotted Wood-Dove	Turtur chalcospilos	ESWD
21	Eurasian Blackcap	Sylvia atricapilla	EUBL
22	Fork-tailed Drongo	Dicrurus adsimilis	FTDR
23	Golden-breasted Bunting	Emberiza flaviventris	GBBU
24	Grey Apalis	Apalis cinerea	GRAP
25	Grey-backed Camaroptera	Camaroptera brevicaudata	GBCA
26	Grey-capped Warbler	Eminia lepida	GCWA
27	Hadada Ibis	Bostrychia hagedash	HAIB
28	Hartlaub's Turaco	Tauraco hartlaubi	HATU
29	Holub's Golden Weaver	Ploceus xanthops	HGWE
30	Montane White-eye	Zosterops poliogastrus	MOWE
31	Mountain Yellow Warbler	Iduna similis	MYWA
32	Northern Double-collared Sunbird	Cinnyris reichenowi	NDCS
33	Olive Sunbird	Cyanomitra olivacea	OLSU
34	Olive Thrush	Turdus olivaceus	OLTH
35	Pied Crow	Corvus albus	PICR
36	Red-chested Cuckoo	Cuculus solitarius	RCCU
37	Red-headed Weaver	Anaplectes rubriceps	RHWE
38	Ring-necked Dove	Streptopelia capicola	RNDO
39	Ruppell's Robin-Chat	Cossypha semirufa	RURC
40	Silvery-cheeked Hornbill	Bycanistes brevis	SCHO
41	Southern Black Flycatcher	Melaenornis pammelaina	SBFL
42	Speckled Mousebird	Colius striatus	SPMO
43	Spectacled Weaver	Ploceus ocularis	SPWE
44	Spot-flanked Barbet	Tricholaema lacrymosa	SFBA
45	Tambourine Dove	Turtur tympanistria	TADO
46	Tawny-flanked Prinia	Prinia subflava	TFPR
47	Tropical Boubou	Laniarius major	TRBO
48	Variable Sunbird	Cinnyris venustus	VASU
49	White-browed Robin-Chat	Cossypha heuglini	WBRC
50	White-eyed Slaty Flycatcher	Melaenornis fischeri	WESF
51	Yellow Bishop	Euplectes capensis	YEBI
52	Yellow-breasted Apalis	Apalis flavida	YBAP
53	Yellow-rumped Tinkerbird	Pogoniulus bilineatus	YRTI
54	Yellow-whiskered Greenbul	Eurillas latirostris	YWGR

Figure 4.

Photographs of birds taken at the DeKUWC. All Photographs by CwM.

a: African Dusky Flycatcher
b: Montane White-eye
c: Silvery-cheeked Hornbill
d: Tropical Boubou

Point Count Data

Table 2 shows the result of the point counts conducted on 5th January, 2016 while Table 3 shows the result of the point counts on 28th January, 2016. The number of individuals recorded at each location is shown.

Table 2.

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Results of the point count on 5th January, 2016. The number of individuals (NOI) observed at various locations is indicated.

#	Species	Point Count Location										NOI
#	Species	A	B	C	D	E	F	G	H	I	J	NOI
1	Red-headed Weaver	2										2
2	African Paradise Flycatcher	1	1									2
3	Cinnamon-chested Bee-eater	1										1
4	Common Bulbul		3	1	1		1		1	1	3	11
5	Black-collared Apalis		1									1
6	Black-backed Puffback		1									1
7	Yellow-whiskered Greenbul			1	1			1	1		1	5
8	Variable Sunbird			1	1	1					1	4
9	Tropical Boubou			1								1
10	African Golden-breasted Bunting			1								1
11	Grey-backed Camaroptera			1			1	1				3
12	Eurasian Blackcap				1							1
13	Yellow-breasted Apalis					1						1
14	Ring-necked Dove						1					1
15	Yellow-rumped Tinkerbird							2		1		3
16	Augur Buzzard								1			1
17	African Dusky Flycatcher								1			1
18	Grey Apalis									1		1
19	Spectacled Weaver									1		1
20	Tambourine Dove										1	1
21	Eastern Double-collared Sunbird										1	1
22	Chinspot Batis										1	1
23	Southern Black Flycatcher										1	1
24	Speckled Mousebird										4	4
25	Olive Thrush										1	1
26	African Grey Flycatcher										1	1
	Number of Species	3	4	6	4	2	3	3	4	4	10

Table 3.

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Results of the point count on 28th January, 2016. The number of individuals (NOI) observed at various locations is indicated.

#	Species	Point Count Location										NOI
#	Species	K	L	M	N	O	P	Q	R	S	T	NOI
1	Tropical Boubou	2	1				1	4				8
2	Grey-backed Camaroptera	2	1	1	1	1	3	2	2	1	1	15
3	Tawny-flanked Prinia	2										2
4	Yellow-whiskered Greenbul	1	2				1	2			1	7
5	Variable Sunbird	3	2		1			1		3	1	11
6	Common Bulbul	1		1	1		1		1	1		6
7	Holub's Golden Weaver		1									1
8	White-eyed Slaty Flycatcher			1								1
9	Ring-necked Dove			1								1
10	Chinspot Batis				1							1
11	Yellow-rumped Tinkerbird							1				1
12	Yellow-breasted Apalis								1			1
13	Silvery-cheeked Hornbill									6		6
14	Black-backed Puffback									1		1
15	Collared Sunbird									1		1
16	Montane White-eye									2	1	3
17	Black Saw-wing										1	1
	Number of Species	6	5	4	4	1	4	5	3	7	5

Audio Recordings

Audio recordings were obtained using the Raspberry Pi based acoustic recorders from eight locations within the DeKUWC. A total of 2701 recordings were obtained. The locations are labeled 1-8 and are shown in the map on Fig. 3b. The acoustic recorder is described in the additional information section.

To determine the bird species present at the recording locations, a subset of the recordings in each location were carefully listened to and annotated. At each location around 20 recordings were annotated with the following information about each recording noted.

Date
Time
Location
Latitude
Longitude
Elevation in meters
Foreground species
Background species
Remarks

The foreground species included those species judged to be close to the microphone and clearly recorded. Background species on the other hand were species which could be identified but were judged to be far from the microphone. Remarks about the recording included information about any background noises and other features deemed noteworthy. For example, cow bells from the neighboring Kabiruini forest were heard on a number of recordings indicating presence of herders and their livestock in the forest. Engine noise was also prominent on recordings obtained near the road. It is important to monitor such sounds as they can be indicators of potential human-wildlife conflict and threats to biodiversity.

Table 4 shows a sample of the annotations for the audio recordings. The species are indicated using a four-letter code described in Pyle and DeSante (2003). The complete file is included in the supplementary material (Suppl. material 1). Each recording has a filename which indicates the location and time of the recording. For example the first file in Table 4, 1-2016-01-05-10-40-01, was recorded at location 1 on 5th January 2016 at 10:40 am.

Table 4.

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Annotation of audio recordings obtained at the DeKUWC (FS= Foreground Species, BS= Background Species)

Filename	FS	BS	Remarks
1-2016-01-05-10-40-01	YWGR	GBCA	Engine noise in the background
1-2016-01-05-11-10-01	TRBO	HATU
1-2016-01-05-12-35-01	GBCA		Sound of engine; crow and insect in the background
1-2016-01-05-12-40-01	GBCA	TADO;HATU	Engine noise in the background
1-2016-01-05-13-20-01	COBU	YRTI
1-2016-01-05-13-40-01	GBCA	TADO
1-2016-01-06-06-30-01	GBCA	YWGR	Robin-Chat singing in the background
1-2016-01-06-06-35-01	YWGR	OLTH;HATU
1-2016-01-06-06-40-02	GBCA	COBU;HAIB
1-2016-01-06-07-00-01	GBCA;BBPU;PICR
1-2016-01-06-07-35-01	BBPU;ABCR;BHOR
1-2016-01-06-07-40-01	GBCA	YRTI
1-2016-01-06-08-05-01	COBU;YWGR;SCHO
1-2016-01-06-08-55-02	GBCA	BBPU;TRBO
1-2016-01-06-09-30-01	HAIB
1-2016-01-06-09-40-02	GBCA	BWWA;YRTI
1-2016-01-06-10-45-01	YRTI	TRBO;GBCA;BWWA
1-2016-01-06-12-30-01	FTDR	YRTI
1-2016-01-06-14-05-01	GBCA;YRTI
1-2016-01-06-14-10-01	YWGR;FTDR

Recorded Species

We obtained recordings from 36 of the 54 species observed in the study. Table 5 shows the number of foreground recordings per species while Table 6 shows the number of background recordings per species. Both lists are in descending order with the most recorded species appearing first. We see that the Yellow-whiskered Greenbul (Eurillas latirostris) is the most prominent species in the recordings. The Yellow-whiskered Greenbul is a very vocal species which makes it very easy to detect even during point counts. When making inferences about the abundance of bird species, it is important to take this into account to avoid over-estimating the abundance of vocal species.

Table 5.

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Number of foreground recordings per species.

Position	Common Name	Scientific Name	Number of Recordings
1	Yellow-whiskered Greenbul	Eurillas latirostris	88
2	Grey-backed Camaroptera	Camaroptera brevicaudata	52
3	Hartlaub's Turaco	Tauraco hartlaubi	30
4	Yellow-rumped Tinkerbird	Pogoniulus bilineatus	29
5	Tambourine Dove	Turtur tympanistria	19
6	Tropical Boubou	Laniarius major	17
7	Black-backed Puffback	Dryoscopus cubla	11
8	Silvery-cheeked Hornbill	Bycanistes brevis	7
9	Common Bulbul	Pycnonotus barbatus	5
10	Ruppell's Robin-Chat	Cossypha semirufa	4
11	Olive Thrush	Turdus olivaceus	3
12	Fork-tailed Drongo	Dicrurus adsimilis	3
13	Collared Sunbird	Hedydipna collaris	3
14	Black-headed Oriole	Oriolus larvatus	2
15	African Paradise Flycatcher	Terpsiphone viridis	2
16	Brown Woodland Warbler	Phylloscopus umbrovirens	2
17	Red-chested Cuckoo	Cuculus solitarius	2
18	Olive Sunbird	Cyanomitra olivacea	2
19	Chinspot Batis	Batis molitor	1
20	Blue-mantled Crested Flycatcher	Trochocercus cyanomelas	1
21	African Dusky Flycatcher	Muscicapa adusta	1
22	Black-throated Wattle-eye	Platysteira peltata	1
23	Cape Robin-Chat	Cossypha caffra	1
24	Hadada Ibis	Bostrychia hagedash	1
25	Abyssinian Crimsonwing	Cryptospiza salvadorii	1
26	Pied Crow	Corvus albus	1
27	White-browed Robin-Chat	Cossypha heuglini	1
28	Variable Sunbird	Cinnyris venustus	1

Table 6.

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Number of background recordings per species.

Position	Common Name	Scientific Name	Number of Recordings
1	Yellow-whiskered Greenbul	Eurillas latirostris	59
2	Hartlaub's Turaco	Tauraco hartlaubi	38
3	Tropical Boubou	Laniarius major	32
4	Grey-backed Camaroptera	Camaroptera brevicaudata	32
5	Yellow-rumped Tinkerbird	Pogoniulus bilineatus	31
6	Tambourine Dove	Turtur tympanistria	29
7	Black-backed Puffback	Dryoscopus cubla	10
8	Brown Woodland Warbler	Phylloscopus umbrovirens	6
9	Silvery-cheeked Hornbill	Bycanistes brevis	6
10	Black-headed Oriole	Oriolus larvatus	5
11	Collared Sunbird	Hedydipna collaris	5
12	Common Bulbul	Pycnonotus barbatus	4
13	Olive Thrush	Turdus olivaceus	4
14	Chinspot Batis	Batis molitor	3
15	African Paradise Flycatcher	Terpsiphone viridis	2
16	Northern Double-collared Sunbird	Cinnyris reichenowi	1
17	Emerald-spotted Wood-Dove	Turtur chalcospilos	1
18	Cape Robin-Chat	Cossypha caffra	1
19	Grey-capped Warbler	Eminia lepida	1
20	Black-throated Wattle-eye	Platysteira peltata	1
21	Black Cuckoo	Cuculus clamosus	1
22	Mountain Yellow Warbler	Iduna similis	1
23	Hadada Ibis	Bostrychia hagedash	1
24	Olive Sunbird	Cyanomitra olivacea	1
25	Yellow-breasted Apalis	Apalis flavida	1
26	Yellow Bishop	Euplectes capensis	1
27	Spot-flanked Barbet	Tricholaema lacrymosa	1
28	Variable Sunbird	Cinnyris venustus	1

Spatial Distribution of Bird Species.

Table 7 shows the number of foreground recordings per location for each of the species observed during the study. Table 8 shows the spatial distribution of all species identified in the recordings, both in the foreground and background of recordings. This allows us to infer the spatial distribution of species. We see that some species such as the Hartlaub's Turaco are highly concentrated in a single location while species such as the Yellow-whiskered Greenbul are more widespread.

Table 7.

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Spatial distribution of foreground species. The number of foreground recordings per location for each of the species is indicated.

#	Species		Recorder Location
#	Common Name	Scientific Name	1	2	3	4	5	6	7	8
1	Abyssinian Crimsonwing	Cryptospiza salvadorii	1	0	0	0	0	0	0	0
2	African Dusky Flycatcher	Muscicapa adusta	0	0	0	0	0	1	0	0
3	African Paradise Flycatcher	Terpsiphone viridis	0	1	0	1	0	0	0	0
4	Black-backed Puffback	Dryoscopus cubla	2	3	0	2	0	4	0	0
5	Black-headed Oriole	Oriolus larvatus	1	0	0	0	0	0	0	1
6	Black-throated Wattle-eye	Platysteira peltata	0	0	0	1	0	0	0	0
7	Blue-mantled Crested Flycatcher	Trochocercus cyanomelas	0	0	0	0	0	0	0	1
8	Brown Woodland Warbler	Phylloscopus umbrovirens	0	1	0	0	0	0	0	1
9	Cape Robin-Chat	Cossypha caffra	0	0	0	0	0	1	0	0
10	Chinspot Batis	Batis molitor	0	0	0	0	0	0	0	1
11	Collared Sunbird	Hedydipna collaris	0	0	1	1	0	0	0	1
12	Common Bulbul	Pycnonotus barbatus	2	1	1	1	0	0	0	0
13	Fork-tailed Drongo	Dicrurus adsimilis	2	1	0	0	0	0	0	0
14	Grey-backed Camaroptera	Camaroptera brevicaudata	10	12	1	1	7	13	1	7
15	Hadada Ibis	Bostrychia hagedash	1	0	0	0	0	0	0	0
16	Hartlaub's Turaco	Tauraco hartlaubi	0	1	7	20	0	1	0	1
17	Olive Sunbird	Cyanomitra olivacea	0	0	0	1	0	0	0	1
18	Olive Thrush	Turdus olivaceus	0	0	0	0	0	1	0	2
19	Pied Crow	Corvus albus	1	0	0	0	0	0	0	0
20	Red-chested Cuckoo	Cuculus solitarius	0	0	0	0	1	1	0	0
21	Ruppell's Robin-Chat	Cossypha semirufa	0	1	0	0	0	1	1	1
22	Silvery-cheeked Hornbill	Bycanistes brevis	1	0	0	0	1	1	0	4
23	Tambourine Dove	Turtur tympanistria	0	1	9	9	0	0	0	0
24	Tropical Boubou	Laniarius major	1	3	2	2	1	8	0	0
25	Variable Sunbird	Cinnyris venustus	0	1	0	0	0	0	0	0
26	White-browed Robin-Chat	Cossypha heuglini	0	0	0	0	0	0	0	1
27	Yellow-rumped Tinkerbird	Pogoniulus bilineatus	2	3	5	10	3	6	0	0
28	Yellow-whiskered Greenbul	Eurillas latirostris	4	18	17	18	17	0	0	14
	Number of Species		12	13	8	12	6	11	2	13

Table 8.

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CSV

XLSX

Spatial distribution of species in both foreground and background recordings. The number of recordings per location for each of the species is indicated.

#	Species		Recorder Location
#	Common Name	Scientific Name	1	2	3	4	5	6	7	8
1	Abyssinian Crimsonwing	Cryptospiza salvadorii	1	0	0	0	0	0	0	0
2	African Dusky Flycatcher	Muscicapa adusta	0	0	0	0	0	1	0	0
3	African Paradise Flycatcher	Terpsiphone viridis	0	1	0	3	0	0	0	0
4	Black-backed Puffback	Dryoscopus cubla	5	4	0	2	1	9	0	0
5	Black Cuckoo	Cuculus clamosus	0	0	1	0	0	0	0	0
6	Black-headed Oriole	Oriolus larvatus	1	0	0	0	2	2	1	1
7	Black-throated Wattle-eye	Platysteira peltata	0	0	0	1	1	0	0	0
8	Blue-mantled Crested Flycatcher	Trochocercus cyanomelas	0	0	0	0	0	0	0	1
9	Brown Woodland Warbler	Phylloscopus umbrovirens	2	1	1	0	3	0	0	1
10	Cape Robin-Chat	Cossypha caffra	0	0	0	0	0	1	0	1
11	Chinspot Batis	Batis molitor	0	1	0	1	1	0	0	1
12	Collared Sunbird	Hedydipna collaris	0	0	1	1	1	1	2	2
13	Common Bulbul	Pycnonotus barbatus	4	1	1	1	0	1	0	1
14	Emerald-spotted Wood-Dove	Turtur chalcospilos	0	0	0	0	0	1	0	0
15	Fork-tailed Drongo	Dicrurus adsimilis	2	1	0	0	0	0	0	0
16	Grey-backed Camaroptera	Camaroptera brevicaudata	15	15	8	7	11	14	4	10
17	Grey-capped Warbler	Eminia lepida	0	0	0	0	0	0	0	1
18	Hadada Ibis	Bostrychia hagedash	2	0	0	0	0	0	0	0
19	Hartlaub's Turaco	Tauraco hartlaubi	3	7	17	23	9	1	0	8
20	Mountain Yellow Warbler	Iduna similis	0	0	0	0	0	1	0	0
21	Northern Double-collared Sunbird	Cinnyris reichenowi	0	0	0	0	0	0	0	1
22	Olive Sunbird	Cyanomitra olivacea	0	0	0	1	0	0	0	2
23	Olive Thrush	Turdus olivaceus	2	0	0	0	0	3	0	2
24	Pied Crow	Corvus albus	1	0	0	0	0	0	0	0
25	Red-chested Cuckoo	Cuculus solitarius	0	0	0	0	1	1	0	0
26	Ruppell's Robin-Chat	Cossypha semirufa	0	1	0	0	0	1	1	1
27	Silvery-cheeked Hornbill	Bycanistes brevis	1	0	0	0	2	2	2	6
28	Spot-flanked Barbet	Tricholaema lacrymosa	0	1	0	0	0	0	0	0
29	Tambourine Dove	Turtur tympanistria	4	12	16	15	0	1	0	0
30	Tropical Boubou	Laniarius major	3	6	4	12	4	18	1	1
31	Variable Sunbird	Cinnyris venustus	0	1	0	0	0	0	0	0
32	White-browed Robin-Chat	Cossypha heuglini	0	0	0	0	0	0	0	1
33	Yellow Bishop	Euplectes capensis	0	0	0	0	0	0	0	1
34	Yellow-breasted Apalis	Apalis flavida	0	1	0	0	0	0	0	0
35	Yellow-rumped Tinkerbird	Pogoniulus bilineatus	8	10	9	14	8	8	0	3
36	Yellow-whiskered Greenbul	Eurillas latirostris	5	22	21	30	24	17	7	21
	Number of Species		16	16	10	13	13	18	7	20

Traits coverage

Temporal coverage

Collection data

Usage rights

Use license:

Creative Commons Public Domain Waiver (CC-Zero)

Data resources

Data package title:

DeKUWC Recordings

Number of data sets:

Data set name:

DeKUWC Recorded Species

Download URL:

https://doi.org/10.5061/dryad.69g60

Data format:

CSV

Description:

This file contains a list of the 54 bird species observed during the study.

Column label	Column description
Common Name	Species common name
Scientific Name	Species scientific name
Four Letter Code	Four letter code to identify the species

Data set name:

Recordings Annotation

Download URL:

https://doi.org/10.5061/dryad.69g60

Data format:

Excel

Description:

This file contains a list of the 2701 recordings obtained during the study from the eight recorder locations. Each location has a corresponding sheet in the Excel document. A subset of the 2701 recordings are annotated and for these recordings we have the following information:

Column label	Column description
Filename	File name of the mp3 file
Date	Date of recording
Time	Time of the recording
Location	Place the recording was taken
Latitude	Latitude of the location
Longitude	Longitude of the location
Elevation	Elevation above sea level of the location
Foreground Species	List of species in the foreground of the recording
Background Species	List of species in the foreground of the recording
Remarks	Any remarks on the recording

Data set name:

Audio Recordings

Download URL:

https://doi.org/10.5061/dryad.69g60

Data format:

MP3

Description:

The folder mp3/ contains MP3 files of the 2701 recordings obtained during the study.

Column label	Column description
Filename	File name of the MP3 file

Additional information

Discussion and Conclusion

We have presented a dataset of acoustic recordings obtained within the Dedan Kimathi Wildlife Conservancy in central Kenya. The DeKUWC is part of the Mount Kenya ecosystem which is an important ecological zone in Africa. In addition to being an important water tower, the Mount Kenya ecosystem is home to several important plant and animal species some of which are endemic to the region.

The recordings we present were obtained using a low cost recorder based on the Raspberry Pi microprocessor. The prototype cost approximately $100 and this allowed us to deploy four recorders at a time. The recordings obtained were of good enough quality to allow identification of bird species vocalizations and also other noise sources such as car engines and people. In addition, an initial attempt at automatic classification of a single species, the Hartlaub's Turaco, using these recordings has been successful (wa Maina 2016).

The study involved both point counts and acoustic recording and 54 bird species were observed. Of these, 33 were recorded during the point counts and 36 identified using recordings of their vocalizations. 15 species were identified during both the point counts and using the audio recordings. We see that the use of acoustic recordings allowed the identification of some species which were not observed during the point counts. This could be due to a number of reasons including 1) The acoustic recordings were obtained over the whole day. Thus if a bird was active outside the point count duration it was still captured by the acoustic recorder. 2) The bird vocalizations could be listened to several times to aid identification. On the other hand, a number of species were observed only during the point counts. These included raptors (Augur Buzzard) and species that are not very vocal such as the Black saw-wing. Vocal species such as the Speckled Mousebird recorded only in the point counts could be present in recordings that have not been annotated.

The acoustic recordings revealed the spatial distribution of bird species within the conservancy with some species such as the Yellow-whiskered Greenbul wide spread and others such as the Hartlaub's Turaco more concentrated in a few locations. With these data as a baseline, future studies can be used to monitor any changes to this spatial distribution and help to infer reasons for this change.

This dataset also reveals the effects of roads on wildlife populations. Engine noise is a prominent noise source in the recordings, particularly in the recordings obtained near the road. It was observed that the recorder nearest the major Nyeri-Nyahururu highway (B5) recorded the fewest number of species. As shown in Table 8 , only 7 species were recorded in both foreground and background of recordings at location 7 which is closest to the highway compared to 20 species recorded at the location with the highest number which was located further from the road, location 8. This confirms conclusions from other authors that roads have a major impact on wildlife populations (Votsi et al. 2012, Goodwin and Shriver 2010).

In conclusion, this study has provided a set of acoustic recordings collected using a cheap recorder which can be used to determine vocalizing species present in the recording and also to serve as useful data to train automatic species recognizers. It demonstrates that similar data collected over longer periods can be useful in aiding conservation efforts by effectively and cheaply monitoring ecosystems of interest.

Acoustic Recorder

The recordings in this study were obtained using a Raspberry Pi (RPi) based recorder as shown in Fig. 5. The Raspberry Pi is a cheap credit card sized microprocessor that can be programmed like a desktop computer. In addition, the RPi can be connected to a number of sensors including microphones. The RPi's used in this study run the Raspbian operating system which is similar to Ubuntu https://www.raspberrypi.org. To obtain the recordings, we installed SoX which is an open source program for audio recording and processing http://sox.sourceforge.net/. It allows users to specify parameters such as the duration of the recording and sampling rate. In this study we used a sampling rate of 16kHz and the samples were stored using 16 bit resolution. The script used to set parameters for the SoX program rec is shown in the supplementary material (Suppl. material 2). After recording, the files were processed to ensure the maximum sample magnitude was unity. The recordings were stored using the WAV format. We also generated compressed MP3 files to reduce storage requirements.

Figure 5.

The Raspberry Pi based acoustic sensor system (a) and the system deployed at the DeKUWC (b).

The RPi recorders were powered using a 5V 6250 mAh battery bank similar to the one in Fig. 5a. This battery was able to power the recorder for approximately 28 hours with the recorder programmed to obtain a one minute recording every five minutes. The total cost of the prototype was approximately $100 which is significantly cheaper than most commercially available wildlife recorders such as the Song Meter from Wildlife Acoustics, Inc (http://www.wildlifeacoustics.com/). An itemized budget is included in the supplementary material (Suppl. material 3).

Additional Species

In addition to bird species identified using their vocalizations. The dataset includes the vocalizations of other nocturnal creatures. These include crickets and tree hyraxes. Recordings 4-2016-01-06-00-40-02 and 4-2016-01-06-00-45-01 contain clear recordings of tree hyraxes.

Acknowledgements

We would like to thank the Kenya Education Network (KENET) for financial support to purchase recording equipment and all the wardens at the Dedan Kimathi University Wildlife conservancy especially Mr. Rashid Saidi and Mr. Kaindio Kimathi for support during fieldwork.

Author contributions

CwM: Conceived the study, performed data collection, analyzed the data, designed the acoustic recorder and wrote the manuscript. DM: Performed data collection, reviewed and edited the manuscript. PN: Performed data annotation, reviewed and edited the manuscript.

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Supplementary materials

Suppl. material 1: Annotation File

Authors: Ciira wa Maina, Peter Njoroge

Data type: An Excel sheet with audio file description and annotation.

Brief description:

This file contains the description of the 2701 audio files recorded at the DeKUWC. Of these, around 200 are annotated and this additional information is included.

Filename: AllRecordingsAnnotation.xlsxDownload file (112.52 kb)

Suppl. material 2: Recording Script

Authors: Ciira wa Maina

Data type: software

Brief description:

This script is called to record the acoustic signals for one minute every five minutes. The SoX program rec performs the recording.

Filename: RecordingScript.shDownload file (164.00 bytes)

Suppl. material 3: Acoustic Recorder Cost

Authors: Ciira wa Maina

Data type: Excel spreadsheet

Brief description:

This file gives the cost of the components used to develop the acoustic recorder prototype.

Filename: AcousticRecorderPrototype.xlsxDownload file (3.99 kb)

Endnotes