High-resolution social network data from direct proximity sensing

Fifty individuals of one large natural colony of common vampire bats (D. rotundus) were tagged simultaneously in Panama. Associations with other tagged bats are fluid and highly dynamic both during day and night. For example, Fig 2A shows the course of the meeting history and the dynamic range of degree centrality for a single bat (ID 56) over a 2-day period. The high temporal resolution of meetings (all mobile nodes in reach communicate with each other every 2 s) also makes it possible to infer a behavior such as departure from the roost or movement within the roost. For example, foraging bouts can be identified by a sudden drop in meeting partners at night, which can be verified by contacts to ground nodes outside the roost. Autonomous direct proximity sensing allows monitoring changes in roosting associations, caused by moving among subgroups within the roost (Fig 2B and 2C), and it also allows inferring “social foraging networks” outside the roost (Fig 2D). In addition, every meeting is labeled with a maximum signal strength intensity indicator. This makes it possible to subset the meeting data set according to signal strength, an estimate for proximity [13]. Accordingly, one can distinguish close-contact associations from associations based on merely occupying the same area [14].

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Fig 2. High-resolution association data in wild vampire bats.

(A) Meeting history of a single vampire bat (ID 56; 50 tagged bats in total) with other tagged bats. Red lines show meetings between bat 56 and other tagged bats (right-hand y-axis). The black line shows the degree centrality (number of associated tagged bats, left-hand y-axis) of bat 56 every 2 s. Date and time are on the x-axis. Shaded areas indicate night time. Vertical dashed lines show egocentric social networks at each snapshot of time during roosting (B, C) and foraging (D). Associations with the focal bat are indicated by red lines. Data and software used to create this figure have been archived by GFBio (https://doi.org/10.7479/vd6t-7a92; https://doi.org/10.7479/ytdf-wf05).

https://doi.org/10.1371/journal.pbio.3000655.g002

The social networks created from direct proximity sensing are independent of the whereabouts of the tagged bats and provide an adaptive temporal resolution of seconds. Almost 400,000 individual meetings were recorded during the first 8 days of our field test. The typical approach for collecting social network data from bats has been to observe some or all of the bats within each roost in a sample of identified roosts each day; however, these co-roosting associations (e.g., the works by Wilkinson and colleagues and Wilkinson [15,16]) cannot detect social structure for individuals sharing the same single roost throughout a study. Our system, however, allows complete networks of spatial proximity of all bats every few seconds. This temporal resolution makes changes in social gatherings directly visible if time slices in high-resolution data are small enough [17]. We believe this represents an extraordinary advance for studying such small free-ranging animals, and it allows for an analytical depth that is so far known predominantly from human social networks generated by communication among smart phones or social media [17]. As an example, we have been able to gain a deeper understanding of the intrinsic and extrinsic factors influencing the stability of social relationships in vampire bats by combining captive experiments and proximity sensing in the wild [14]. Tracking associations at high temporal resolution in the wild allowed us to gather evidence for rare and cryptic events, such as maternal guidance in noctule bats [18] and unfamiliar kin recognition in vampire bats [19].

Received signal strength–based localization from angle-of-arrival estimation

Seventeen wireless localization nodes were used to track tagged 11 mouse-eared bats (M. myotis) over an area of approximately 1.5 ha in an old, natural deciduous forest in northern Bavaria (Germany, Forchheim). We were able to reconstruct flight trajectories from foraging mouse-eared bats. Fig 3B shows as an example 2 trajectories of one foraging mouse-eared bat during 2 different nights in early August.

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Fig 3. Tracking bat movements in a forest.

(A) Tracking grid in a deciduous forest of Forchheim, Germany, consisting of 17 localization nodes (gray dots) covering an area of approximately 1.5 ha. Dashed black line: known reference path; blue line and blue shading: estimated path and average localization error obtained by the presented wireless biologging system; yellow lines: 4 individual GPS tracks. (B, C) Estimated flight trajectories of a tagged mouse-eared bat during foraging on August 2nd and 5th. Data and code used to create this figure have been archived by GFBio (https://doi.org/10.7479/vd6t-7a92). GPS, global positioning system.

https://doi.org/10.1371/journal.pbio.3000655.g003

We evaluated the spatial resolution of the tracking system by estimating a trajectory from a defined reference path using unscented Kalman filters. The reference path and estimated trajectory are shown in Fig 3A. The trajectories were calculated from angle-of-arrival estimates of signals impinging on localization nodes. Angles were estimated from difference measurements of received signal strength at 2 orthogonal antenna gain patterns. This procedure in combination with a set of postprocessing techniques for probabilistic multipath mitigation makes the trajectories robust to multipath propagation. The calculated trajectory is based on 4,912 data sets, and 1 set was composed of up to 2 × 17 received signal strength difference measurements (1 per frequency band) if all 17 localization nodes were within the reception range of the mobile node. For comparison, we also analyzed 4 tracks recorded by a 15 g heavy-duty Ornitela GPS tracker, which is commonly used for tracking large birds of up to 450 g body mass. The mean positioning error was 7.30 m for the Ornitela GPS tracker and 5.65 m for the trajectory of the WBN.

We calculated the positioning accuracy at lower densities of the localization grid. Localization was less accurate with fewer localization nodes (Fig 4), but it was robust and comparable to the full tracking grid (17 nodes) when using 15 to 16 nodes. With 12 to 14 nodes, we observed increasing variation in average error rates. With 11 nodes, the mean error was similar to the results from GPS tracking. Variation increased steadily with lower numbers of nodes, and the mean error reached more than 10 m with a maximum error rate of 34 m at 6 nodes. At such low grid densities, the localization results tended to diverge, resulting in increasing positioning errors. In addition, sparser grids lack robustness against multipath scattering. Consequently, the node density may only be reduced to a certain point, although positioning errors remain quite stable (Fig 4).

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Fig 4. WBN tracking performance versus GPS tracking.

Localization errors of a reference path of approximately 300 m by the WBN are shown for different numbers of tracking nodes (6–17) in a deciduous forest of approximately 1.5 ha area. The average positioning error of 4 tracks of a heavy-duty commercial wildlife GPS tracker is shown for comparison by a yellow dashed line. Data and code used to create this figure have been archived by GFBio (https://doi.org/10.7479/vd6t-7a92). GPS, global positioning system; WBN, wireless biologging network.

https://doi.org/10.1371/journal.pbio.3000655.g004

These analyses show that 11 localization nodes over an area of 1.5 ha in a forested habitat might be sufficient to construct high-resolution trajectories comparable in quality to a heavy-duty GPS tracker, which would only last for a few hours using a 15 g device, or to reverse GPS in open desert habitats [10]. Only moderate resources and human effort are needed to cover an area of a few hectares. For example, a setup as described above consisting of 11 localization nodes is deployed and configured by 2 people in 1 to 2 workdays.

Distance verification of packet transmission by long-range telemetry

Transmission distances of data packages were measured in an urban green area. Thirty-four noctule bats (N. noctula) were tagged in a forest within the city of Berlin, and 2 long-range telemetry receivers were placed at a distance of about 1 and 4 km from the forest.

Mobile nodes transmitted a burst for long-range transmission of the mobile node’s time stamp coupled with every mobile node beacon. During a period of 2 weeks, we were able to receive more than 168,000 long-range bursts, which allowed us to successfully recover 9,511 complete time stamps from 32 individual bats. To mitigate the impairment by interfering transmission, 1 complete long-range telemetry packet is split over 24 single-burst transmissions. At the long-range receiver, 24 subsequent bursts are merged to 1 actual long-range packet containing the ID and the bat’s time reference. This transmit scheme assures that the mobile node’s transmit module is only activated for a short time period, avoiding stress on the batteries and hardware. In addition, it avoids interference of other channels by a time-frequency hopping pattern in transmission. Instead of a complete package loss, only a fraction of the collection of bursts might be corrupted, which can be reconstructed by means of error-correction codes at the receiver side. It is only because of this specialized telegram-splitting technique [20] that a long-range transmission under extreme power restrictions and vastly occupied frequency channels becomes possible.

Reception of long-range data should perform best when the tagged bats move in open airspace. However, we recovered a considerable number of these long-range bursts while bats were inside their roosts during the day. We mapped 563 long-range bursts received during the day to the known roosts of the bats, allowing us to measure the transmission distance. Fifty-seven long-range bursts from 4 bats inside their roost were recovered over distances of approximately 4.2 km (between 2 roosts and the receiver at the cogeneration plant). We recovered 506 long-range bursts from 5 tagged bats at distances between 667 and 819 m (between the receiver at the retirement home and one of the aforementioned roosts and an additional roost). Burst retrieval over distances of more than 4 km was surprising. Theoretical calculations predicted transmission distances of about 5 km assuming barrier-free transmission [21]. In the field, however, signals had to pass first through the wooden wall of the tree roost and, second, through the forest’s vegetation, which should greatly reduce transmission distance.

Data recovery is a major challenge in automated lightweight tracking systems. Signal transmissions inherently suffer from limited transmission power under heavy losses because of distance, shadowing, and other interfering signals. Remote downlinks, e.g., per Global System for Mobile Communications (GSM), add considerable weight in the form of circuitry and battery [1]. Many lightweight trackers must therefore be retrieved, or energy harvesting must be used to counterbalance the expenses for remote data download [7,22–24], again adding weight for the required hardware components. When tagged animals move on predictable scales, energy-saving methods like transfer via very high frequency (VHF) or radio modems may be an option to receive data over distances of hundreds of meters to a few kilometers [25]. Our scenario explores options to decrease the energy expense for downloading stored data to a negligible proportion of the overall energy budget (compare Fig 5). For data download over short distances of approximately 100 m, we accumulate and preprocess data on board and use sophisticated communication protocols that maximize data package reconstruction while minimizing energy demand [26,27]. The above described long-range telemetry mode provides an option for robust transmission of small amounts of data at a low rate without the expenditure of additional energy because of the hybrid modulation of the signal. In comparison, other long-range systems for biologging, such as LoRa [12], enable higher transmission rates. However, the bidirectional communication between transmitter and receiver strongly increases the energy demand on the mobile node.

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Fig 5. Energy distribution of software tasks of a mobile node powered by a 22 mAh battery.

Energy demand per software task depends on parameter settings for active/inactive beacon interval (s) and amount of time an animal spends in the localization grid (h). The energy demand is shown for the 7 major software tasks. Zero time in the localization grid (A, B) refers to a pure proximity sensing scenario. Data underlying this figure have been archived by GFBio (https://doi.org/10.7479/vd6t-7a92).

https://doi.org/10.1371/journal.pbio.3000655.g005

Sensor node energy consumption and lifetime

A major strength of WBNs is the ease of adjusting parameters such as sampling rate and in turn energy consumption. These adjustments can maximize runtime for a given battery capacity, or alternatively, maximize sampling rate to obtain higher resolution data. To investigate the impact of the different software task parameters on runtime, we derived a model for energy consumption. We computed examples of runtimes of mobile nodes for 2 battery capacities and different parameter settings (Table 1). For example, the increase in energy consumption when tracking 2 to 4 hours per day can be compensated by extending the mobile node beacon intervals. We achieve runtimes of at least 5 days using a 12 mAh battery (corresponding to a 1 g mobile node) even at the shortest beacon intervals of 2 s (active mode) and with 2 h of high-resolution tracking per day. Depending on the parameter settings, we achieve runtimes of up to 13 d using the smaller battery and 25 d using 22 mAh (Table 1).

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Table 1. Estimated runtimes of mobile nodes for 2 battery capacities of 12 or 22 mAh inferred by an energy model for mobile-node runtime.

Although the model comprises 7 energy consuming tasks, the shown runtimes are based only on varying beacon intervals of mobile nodes and localization time (i.e., animal is within the localization grid). For mobile node beacon intervals, 2 operation modes are possible, depending on whether an animal is within reception range of a ground node (inactive mode) or not (active mode).

https://doi.org/10.1371/journal.pbio.3000655.t001

Fig 5 illustrates the energy consumption of the different software tasks on the mobile nodes of the 6 different scenarios described in Table 1. When localization is disabled (i.e., only proximity sensing), sending out beacons to wake up other mobile nodes to initiate meetings strongly drives the energy demand (Fig 5A). Therefore, modifying the beacon intervals of the mobile node has the highest impact on runtime (Fig 5B and Table 1). When localization is enabled, tagged animals send localization packages whenever they enter the tracking grid. The high duty cycle of sending localization packages (8/s) strongly decreases the runtime (Fig 5C–5E and Table 1). At active/inactive beacon intervals of 2 per 10 s, a daily localization period of 2 h decreases the overall runtime by 10.8% (Fig 5A and 5C and Table 1). At 4 h of localization, the energy demand for localization dominates the overall energy consumption, in particular at high beacon intervals of mobile nodes.

Model-derived runtimes were compared with empirical runtimes from field tests on noctule bats (N. noctula), in which mobile nodes were either powered by a 12 mAh battery or a 22 mAh battery, resulting in masses of mobile nodes of 1.1 to 1.9 g depending on housing. The average runtime was 148 h (max. 209 h) for the small battery, whereas the model predicted 151 h. For the larger battery, average runtime was 280 h (max. 426 h) with a predicted average value of 277 h. For both batteries, the predicted values were very close to the observed (1.8% overestimation and 0.7% underestimation, respectively) indicating that the model is a reliable tool for designing a field study.

Ethics statement

The WBN hardware, software, and functionality

Fig 1 is a schematic overview of the presented WBN, which has been developed within the BATS-initiative (for “Betriebsadaptive Tracking-Sensorsysteme,” a German short title for “dynamically adaptable positioning of bats using embedded communicating sensor systems”). In order to study its performance, we empirically evaluated the 3 major functions of the system: proximity sensing (Fig 1A), high-resolution tracking at local scales (Fig 1B), and long-range telemetry (Fig 1C). See glossary (S1 Table) for definitions of terms.

Proximity sensing

Any given mobile node dyad generates meetings whenever it comes within reception range (5–10 m depending on the environment). The animal-borne mobile node consists of a 22 mm × 14 mm Flex PCB circuit board, which is populated with a central System-on-Chip (EFR32, Silicon Labs) containing an ARM Cortex-M4 core and 2 radio frontends for 868/915MHz and 2.4GHz (S1 and S2 Figs). The transmitter in the sub-GHz frontend periodically sends mobile-node beacons, a signal that contains a wake-up sequence. The rate of beacons is configurable (see below). A low-power wake-up receiver on the mobile node triggers the conventional receiver to receive incoming information on the ID whenever a mobile-node beacon is received from another mobile node. Subsequently, a meeting is created between the communicating mobile-node dyad (Fig 1A left). Whereas a conventional receiver draws a relatively high current in receiving mode waiting for incoming packages, a wake-up receiver achieves this functionality with a low current (yet, at cost of sensitivity and performance). When no further mobile-node beacons are received from the meeting partners for 5 interbeacon intervals, the meeting is closed and stored to memory along with the ID of the meeting partner, meeting duration, maximum received signal strength, and a relative timestamp. The mobile node contains both persistent and volatile random-access memory for data storage.

The conventional receiver of the sub-GHz frontend is periodically activated to observe the presence of a ground node (at a fixed interval of every 2 s), which is indicated by a ground-node beacon, periodically broadcast by the transmitter of each ground node (Fig 1A right). The transmitter supports several configurations defining the main purpose of the ground node and enabling location-dependent adaptive operation of the WBN. (i) A download-dedicated ground node broadcasts a signal that enables transmitting mobile-node data based on a customizable threshold of signal strength received at the mobile node. (ii) A tracking-dedicated ground node positioned within the grid of localization nodes for high-resolution tracking broadcasts a signal that activates the 2.4 GHz frontend in addition to the sub-GHz front end on the mobile node, transmitting “localization packets” at a rate of 8 packets per second. (iii) A presence-detection-dedicated ground node triggers the transmission of “presence signals” by a mobile node and stores incoming signals that can be used to determine presence/absence of tagged individuals (presence at resources or at sleeping sites). Combinations of functionalities (i–iii) may be used in a single ground node if desired (e.g., a tracking-dedicated ground node can also trigger data download). Incoming mobile node data is received by the ground node and stored by a Raspberry Pi (Raspberry PI Foundation, Cambridge, UK) to a SD card along with the ID of the transmitting mobile node and the receiving ground node, respectively, and a timestamp, which is provided by a GPS unit. The Raspberry Pi also hosts a WiFi allowing the user remote data access (software and hardware design can be downloaded at http://coll.mfn-berlin.de/data/10.7479/z5ym-kx58).

Visualization of proximity sensing data is facilitated by the custom-made software “meeting splitter” (see Fig 2). For each specified mobile node ID, the current meeting partners are projected onto a discrete time axis (1 s resolution). We specified a configurable time window around each point on the time axis (5 s in the case of Fig 2). All ongoing meetings, which overlap with the window around the respective point in time, are included in the set of associated bats at this particular point in time. The result per bat is a set of associated bats per each second in the data set. A subsequent automated analysis classifies each meeting as inside or outside the roost, depending on the number of simultaneous meeting partners (not applied in this manuscript).

Received signal strength-based high-resolution tracking

Localization nodes perform field strength measurements, which are collected by WLAN and are processed by a PC including a file system whenever animal-borne mobile nodes enter the localization grid (Fig 1B; localization nodes collect localization packets from mobile nodes; the transmission is triggered by a ground node). Each localization node comprises a software-defined radio (consisting of a radio frequency frontend, a highly integrated analog-to-digital converter, a field-programmable gate array and a microcontroller) and 2 receiving antenna gain patterns each with 2 main lobes (Fig 1B, red and blue pattern, respectively). The bilobed shape indicates the directional sensitivity of the antenna, and the direction of each lobe represents its maximum in sensitivity. The red pattern is rotated by 90° compared to the blue pattern, and both are simultaneously used to estimate the AoA of the localization packages transmitted by the animal-borne mobile nodes. The difference in received signal strength of the 2 patterns relates to AoA: If the difference—received signal strength of the blue pattern minus received signal strength of the red pattern—is maximum, the wave front impinges on the localization node either from east or west; if the received signal strength difference is minimum, the direction of arrival is north or south. Accordingly, there are 4 options for the AoA if the difference is zero: northeast, northwest, southeast, or southwest. These ambiguities are resolved by fusing measurements of several localization nodes.

This design allows us to exploit not only error-prone absolute field strength measurements [55] but also fail-safe AoA. These are not affected by faulty propagation laws or shadowing effects, because both error sources disappear when forming the received signal strength differences. The angular resolution of the AoA estimates improves with increasing ambiguity of the antenna pattern designs. However, more localization nodes have to be in reach to resolve the ambiguity [56]. During the Forchheim field trial, we collected up to 272 angle estimates per second when all 17 localization nodes were in reception range.

To further improve localization accuracy, we exploited 3 sources of information ((a) model-based Bayesian positioning, (b) frequency diversity, (c) retrodiction), which increase robustness against multipath propagation. This effect complicates the positioning process, in particular in structurally complex environments because wave fronts impinge a localization node out of the different directions of multiple reflectors (e.g., surrounding vegetation). The information sources to counteract multipath-related adverse effects are described in the following:

Long-range telemetry

Our long-range telemetry approach aimed at transmitting long-range bursts from mobile nodes over distances of up to several kilometers—much longer distances than our download-dedicated ground nodes would allow for—within the city of Berlin, under harsh shadowing by obstacles (vegetation, buildings, etc.) or in presence of numerous interferes. We periodically transmitted “long-range bursts,” i.e., relative time stamps in the form of seconds since mobile node start-up generated by a simple clock counter. These time stamps are crucial for postprocessing of meetings because they allow accounting for clock drift on the mobile node (depending on the specific aim of the study other data types such as sensor data could be transmitted instead). We embedded the long-range functionality into the existing modulation scheme using a hybrid phase-alternating modulation on top of the pure amplitude-modulated wake-up sequences of the mobile-node beacon [60]. As a consequence of the extreme energy limitation of the mobile node, we ensured the required signal to noise ratio (SNR) by counterbalancing the rate and the desired transmission distance. The combination of the hybrid modulation, the channel encoding procedure [21,60], and the “Telegram-splitting” technique [20] enables an ultra-low power long-range transmission without additional expenditure of energy. The long-range bursts were received at 2 long-range receivers, which were deployed on exposed sites (rooftops) at distances of approximately 200 to 1,800 m (retirement home; 52°27'13"N 13°30'19"E) and 3,300 to 4,500 m (cogeneration plant; 52°29'18"N 13°29'36"E) to the proximate respectively ultimate border of the urban forest where the roosts of the tracked bats were located (forest center approximately 52°27'13"N 13°29'40"E).

We quantified communication distances in the field, which was possible when a tagged bat occupied a known roost and was simultaneously received by the long-range receiver. We therefore matched time stamps of signals received simultaneously by ground nodes at roosting sites and at long-range receivers. In case of a match, we quantified the distances between roosts and long-range receivers in the R package geosphere using the Haversine function [61]. The empirically assessed communication distances have then been compared to a theoretical model of long-range transmission distances [62]. This model evaluates achievable rate and distance of transmission based on the energy relation of the SNR, presuming the transmission power given by the mobile node’s hardware configuration and a desired target payload rate. For simulating the channel characteristics faced by the mobile node, the model comprises parameters like the path loss in dependence of the signal-center frequency, the transmission distance, and receiver and transmitter heights. Environmental influences like attenuation by obstacles, multipath propagation, or unpredictable rotation of the mobile node’s rod antenna are incorporated by means of a random variable, stating the superimposed attenuation effects. Based on these assumptions, we were capable of overcoming path losses of over 150 dB for a distance of 5 km and more, under reasonable rates of packet loss [21], thus accomplishing an ultra-robust implementation supporting payload data rates of a few bits per second.

Sensor node energy consumption and runtime

A crucial aspect for biologging is knowledge on the runtime of the sensor nodes. Static program-code analysis methods of the mobile node are able to determine upper bounds on the nodes’ runtime [63]. However, in the context of the presented WBN, precise estimates for the average uptimes of the system proved to be more beneficial for the empirical studies than upper bounds for the lifetime. Consequently, we focused on an energy model to determine the average runtime of the mobile nodes, which is strongly dependent on the tasks executed by the software. Our models are based on measurements of each executed task in combination with empirically determined activity parameters of each task. That way, we ensure highest accuracy for our model. In our setting, 7 different tasks are implemented: (i) standby, (ii) sending mobile-node beacons, (iii) receiving mobile-node beacons, (iv) observing ground-node availability, (v) transmitting data to a ground node, (vi) sending localization packets, and (vii) sending presence signals (see S1 Table for definition of terms).

We determined the runtime by using the specific energy demand for a task and by translating it to an average current draw. With the average current draw and a given battery capacity, the runtime can be computed as follows: ŋDCDC represents the efficiency of the DCDC-converter, which is permanently active and consumes energy. Determining ŋDCDC is impractical, because it highly depends on the actual current drain of the application for the entire runtime. For this reason, we assume a fixed efficiency of 0.95, which translates to only 95% of the battery capacity being available for software tasks. This way, losses caused by the DCDC and parasitic discharges of the battery are modeled in a coarse-grained manner.

The idle current during standby is given in a current draw, which does not require any further calculations. The other tasks (e.g., observing ground-node availability, sending localization packets) are executed in predefined cycle times (duty cycle). Based on the measured energy demand and the duty cycle, we calculated an average current draw for each task. The energy demand for each task was measured in the lab with an Agilent DC power analyzer precise source meter. In the case of a localization packet, which is sent every 128 ms, the average current draw can be expressed as follows: The average time spent inside the localization grid (T_localization) per day is strongly dependent on the species-specific animal behavior and the experimental design. For the calculations presented here, we set the daily localization period to 2 or 4 h, respectively.

Observing a ground node in receiving range is carried out at a fixed duty cycle of 2 s. Here, the task is independent of the behavior of the tracked animal, and the energy demand is calculated as follows: The transmission rate of mobile-node beacons and presence signals is adaptive based on the contact to a ground node (i.e., a mobile node near a ground node at a roost will decrease the duty cycle in comparison to a mobile node on a foraging animal which is not in reception range of a ground node). In turn, the energy demand for sending beacons and presence signals highly depends on the behavior of the tracked study species and the individual animal (e.g., time spent near ground nodes at roosting sites). We therefore used empirical data obtained in the Berlin field test to inform our energy model with realistic averaged parameter values for duty cycles of each task and the amount of transmitted data. We quantified the average time tagged bats spent in reception range of a ground node (inactive mode, decreased duty cycle) versus the time bats spent outside the reception range of any ground node (active mode, increased duty cycle). The common noctule bats in the Berlin field test spent on average 47% of the observation time in the inactive mode, and the energy demand for transmitting beacons and presence signals calculates as follows: Receiving a mobile-node beacon depends on the duty cycle at which beacons are transmitted and on the number of mobile nodes in receiving range. During the Berlin field test, we calculated the average number of 2.05 maximum parallel meetings: For data download to a ground node, we assumed static energy consumption (the energy demand for sending a data packet highly depends on the size of the packet to be transmitted [27]). The number of data packets to be transmitted is again dependent on the behavior of the tracked animal (depending on how many meetings an individual accumulates). Mobile nodes on common noctule bats sent on average 23.7 packages per hour to a ground node. Thus the current draw can be denoted as Based on these calculations, we matched the estimated average runtimes to the observed runtimes during the Berlin field test (based on the last beacon or packet received from each individual tagged bat).

Adaptive operation, scalability, and reconfiguration

The adaptive operation contributes to energy efficiency. We define location-specific communication schemes on the mobile nodes which are initiated by ground nodes. At a noctule bat day roost, e.g., ground nodes activated the inactive beacon interval where mobile-node beacons for meeting generation were only sent every 10 s. When tagged bats leave their roost and move beyond the reception range of the ground node, the mobile node switches to the active interval, sending a mobile-node beacon every 2 s, which increases the probability to detect also very short meetings in comparison to the inactive rate. Similarly, localization packets, which strongly increase the energy demand, should only be sent when the tagged animal moves within the tracking grid and are therefore triggered by a ground node within the grid.

We can track multiple individuals simultaneously. Our current design allows for the observation of up to a theoretical maximum of 60 individuals. Field deployments containing 11 to 50 tagged bats empirically validated this targeted scalability. The scale of the localization grid can be adapted to the ranges required for experimental setups. Although we tracked mouse-eared bats on approximately 1.5 ha, smaller areas might be sufficient to track, e.g., rodents (bank voles, which showed a density of 40–162 individuals per hectare, have been tracked on less than 0.5 ha using automated VHF telemetry [64]; see ATLAS-system in Table 2). Tracking grids larger than 1.5 ha are certainly possible from a technological point of view. Yet, one has to keep in mind that effort for maintenance (e.g., replacing power sources for localization nodes) scales with the size of the tracking grid.

Because settings for communication schemes are sometimes difficult to pick a priori, we built an option for reconfiguration of so-called soft settings (active/inactive rate of mobile-node beacons, received signal strength thresholds for data download, localization interval, or timeout duration after which a running meeting is terminated, etc.). Four values for every soft setting (e.g., active rate 2 s, 4 s, 10 s, 30 s) can be defined a priori, and during operation ground nodes can be used to trigger a switch between these predefined values at the mobile node.

Field deployments

The presented system is modular, and hardware setup and software configurations can be tailored to a specific use case. We evaluated the system’s performance during 3 major field studies by applying mobile nodes to vampire bats, noctule bats, and mouse-eared bats with body mass of 27 to 48 g, 18 to 35 g, and 22 to 28 g, respectively. Although at least 2 of the 3 major functionalities (proximity sensing, high-resolution tracking, long-range telemetry) have been used in all 3 field studies, we focus on one specific functionality per deployment. The proximity sensing performance was best demonstrated in the vampire bats study because the highest number of individuals was tagged here and group cohesion was high—ideal circumstances to test system performance in the presence of a large number of tagged individuals. We demonstrated high-resolution tracking with mouse-eared bats because individuals of this species regularly revisit their foraging grounds and can therefore reliably be tracked within an area of 1 to 2 ha across multiple days. We assessed transmission distances of long-range telemetry in noctule bats because they frequently switched roosts, and long-range telemetry provided a valuable opportunity to obtain data from individuals that moved to unknown locations. In general, we chose to use bats to demonstrate the high performance of this system because small body mass, nocturnal activity (no sunlight exposure), and flight confront tracking systems with major challenges. A system that is capable of automated tracking of bats may be likely to work for tracking other small terrestrial taxa as well.

Proximity sensing in vampire bats

We tagged 50 common vampire bats (D. rotundus; 44 adult females, 6 subadults) from a colony roosting in a cave tree near Tolé, Panama, to document social networks with high resolution. Field work was conducted during September and October 2017. Mobile nodes were powered by a 22 mAh LiPo battery and housed in a 3D-printed plastic case, resulting in a total mass of 1.8 g. One download-dedicated ground node was positioned inside the roost, and 5 ground nodes were placed on surrounding cattle pastures to detect the presence of foraging or commuting bats.

Long-range telemetry in noctule bats

We captured and tagged 34 common noctule bats (N. noctula; 19 adult females and 15 juveniles) from 2 bat boxes in a nursing colony in an urban forest in the city of Berlin, Germany (“Königsheide Forst”) [18]. Mobile nodes were powered by either a 12 mAh or a 22 mAh battery and were housed either in a 3D-printed plastic case or in a fingertip of a nitrile lab glove that was sealed with glue. Total mass varied between 1.1 and 1.9 g depending on housing and battery. We positioned 5 ground nodes underneath known roosts to document the presence of individual bats and to remotely download data. In addition, we set up 2 long-range receivers to evaluate model-based predicted data retrieval over distances of up to 4 to 5 km [21]. This opportunity is particularly valuable to retrieve data of tagged individuals that moved to an unknown roost.

High-resolution tracking of mouse-eared bats

We captured 11 mouse-eared bats (M. myotis) using mist nets set up at ground level in a mature deciduous forest near Forchheim, Germany. When hunting for ground beetles, mouse-eared bats are faithful to their foraging sites for consecutive days. We therefore mist-netted bats at an attractive foraging site (rather than catching them from a roost) in order to track repeated bouts by returning individuals over the course of several days. Mobile nodes were powered by 22 mAh batteries and housed in fingertips of nitrile lab gloves (total mass 1.4 g). At the capture site, we installed a tracking grid consisting of 17 localization nodes covering roughly an area of 1.5 ha (see Fig 3). Distance between tracking stations varied between approximately 25 and 40 m. The irregular configuration was because of the presence of thick trees. We aimed at positioning tracking stations at least 3 to 5 m away from trees to reduce shielding of the signal. We set up a polygon-shaped reference path for estimating localization errors and determined the true position of the corners using a Leica Robotic Total Station TS16 (positioning error <5 cm). Corners were connected using strings, and we walked either a sensor node or a GPS tracker (Ornitela OrniTrack-15; a 15 g solar powered GPS-GSM/GPRS tracker; maximum logging rate 1 fix per second at a lifetime of approximately 4 h without solar harvesting) along the calibration path and calculated the average localization error based on the obtained tracks.