Congratulations to Rachel for being awarded an EPSRC New Investigator award for her project “Modelling removal and re-introduction data for improved conservation”.
Congratulations to Rachel for being awarded an EPSRC New Investigator award for her project “Modelling removal and re-introduction data for improved conservation”.
Click here to submit your application.
Project description: Capture-recapture data are commonly collected and modelled for the study of wildlife populations (McCrea and Morgan, 2014). Existing capture-recapture models typically assume independence between individuals, with no network structure. Hence, the probability of capture, survival, or movement of particular individuals is assumed to be unaffected by events occurring to other individuals, or actions of these individuals, in the same population. The assumption of independence between individuals gives rise to likelihood functions that are simple products of probabilities of individual capture histories.
However, animal populations are structured by interaction networks among individuals and many species tend to live in social groups that result in these interaction networks differing from random (Wey et al., 2008; Pinter-Wollman et al., 2014; Krause et al., 2015;). In these cases, probabilities of certain events involving particular individuals might be related to their position in the social network. For example, individuals that are strongly connected in a network may be more likely to be captured at the same event. However, network relationships may also result in covariation in survival, or associated traits, between individuals. For example, the spread of directly transmitted infectious diseases will be linked to network structure and this could result in social covariance in survival if infection elevates mortality. Therefore, the survival probability and capture histories of individuals in the same network are expected to change according to the histories of all individuals in that network.
Moreover, there may an additional level of clustering, with certain networks, which are in close proximity for example, affecting each other, maybe to a less, but still not negligible extent. Additionally, it is possible that network structure changes over time, with network membership, and as a result network behaviour, also changing over time. Capture-recapture models offer a possibility of modelling network structure, while accounting for changing membership over time.
A wide range of statistical social network models have been developed, especially within sociology, and are increasingly applied across a range of fields (Cranmer et al., 2017; Silk et al. 2017). However, no such modelling approach exists for capture-recapture data. Ignoring a potential network structure, and hence ignoring dependence between individuals in the same network or dependence between linked networks, may lead to biased estimates of demographic parameters of interest, such as survival probability. Further, incorporating network structure within existing capture-recapture models offers a statistical framework to understand longer-term network dynamics that is more robust to turnover in membership than many existing statistical models of networks.
The project will develop network models for capture-recapture data, motivated by a long-term data set on badgers. The European badger Meles meles is a medium-sized carnivorous mammal widely distributed across the Western Palearctic. In high density populations badgers live in territorial social groups, and individuals interact frequently with other group members and much more rarely with individuals from neighbouring groups (Weber et al. 2013 Current Biology). One such high density population in South West England has been studied using mark-recapture methods for over 40 years providing a unique long-term demographic dataset ideally suited to investigate the questions outline above (McDonald et al., 2018). Capture-recapture models (e.g. McDonald et al., 2016) and social network approaches (e.g. Weber et al., 2013, Silk et al. 2018) have been used to provide valuable insights into this population, but have yet to be combined within a single approach. Therefore, this project offers an important opportunity to gain a new understanding as to how social interactions relate to key demographic processes.
Although the project is motivated by a capture-recapture data set, the methods developed and applied will be more generally applicable to the study of network data. Given the size and complexity of the available data set, the developed methods will need to be scalable to large data sets, making them even more appealing and relevant in the study of network data.
References
Cranmer, S. J., Leifeld, P., McClurg, S. D., & Rolfe, M. (2017). Navigating the range of statistical tools for inferential network analysis. American Journal of Political Science, 61(1), 237-251
Krause, J., James, R., Franks, D. W., & Croft, D. P. (Eds.). (2015). Animal social networks. Oxford University Press, USA.
McCrea, R. S., & Morgan, B. J. (2014). Analysis of capture-recapture data. CRC Press.
McDonald, J. L., Robertson, A., & Silk, M. J. (2018). Wildlife disease ecology from the individual to the population: Insights from a long‐term study of a naturally infected European badger population. Journal of Animal Ecology, 87(1), 101-112.
Pinter-Wollman, N., Hobson, E. A., Smith, J. E., Edelman, A. J., Shizuka, D., De Silva, S., … & Fewell, J. (2013). The dynamics of animal social networks: analytical, conceptual, and theoretical advances. Behavioral Ecology, 25(2), 242-255.
Silk, M. J., Croft, D. P., Delahay, R. J., Hodgson, D. J., Weber, N., Boots, M., & McDonald, R. A. (2017). The application of statistical network models in disease research. Methods in Ecology and Evolution.
Silk, M. J., Weber, N. L., Steward, L. C., Hodgson, D. J., Boots, M., Croft, D. P., … & McDonald, R. A. (2018). Contact networks structured by sex underpin sex‐specific epidemiology of infection. Ecology letters, 21(2), 309-318.
Weber, N., Carter, S. P., Dall, S. R., Delahay, R. J., McDonald, J. L., Bearhop, S., & McDonald, R. A. (2013). Badger social networks correlate with tuberculosis infection. Current Biology, 23(20), R915-R916.
Wey, T., Blumstein, D. T., Shen, W., & Jordan, F. (2008). Social network analysis of animal behaviour: a promising tool for the study of sociality. Animal behaviour, 75(2), 333-344.
Applicants should have a good degree in statistics, mathematics, computer science, or related subjects with a strong numerical component. They should be comfortable working with data and learning new methods, determined, and interested in engaging with the practical applications of their research.
Supervisors
The supervisory team brings together multidisciplinary expertise covering statistics and ecology.
Dr Eleni Matechou and Dr Xue Wang, University of Kent
Dr Matthew Silk, University of Exeter
This studentship will be based in the Institute of Zoology, London and will be affiliated with the School of Mathematics, Statistics and Actuarial Science, University of Kent.
Click here to submit your application by the 8th of January.
Supervisors
Dr John Ewen (Institute of Zoology)
Dr Rachel McCrea (University of Kent)
Dr Nik Cole and Dr Richard Young (Durrell Wildlife Conservation Trust)
Dr Stefano Canessa (Institute of Zoology/University of Ghent)
Project Description
Reintroduction biology assists in providing the science support for improved reintroduction outcomes. Both the frequency of reintroductions and publication of reintroduction science are increasing, yet their integration remains limited1. Embedding science within reintroduction decisions faced by practitioners offers a strategic use of evidence to make the best management decisions. The skills required by scientists need developing including group facilitation, elicitation of expert knowledge, quantitative modelling of predicted and observed outcomes of management alternatives, risk analysis and optimisation. Our project offers a package where these aspects will be developed to produce a trained professional able to engage with multi-stakeholder groups undertaking species recovery. The student will develop and apply these skills to a lesser night gecko (LNG, Nactus coindemirensis) reintroduction in Mauritius.
Reintroductions of Mauritian reptiles to rebuild island communities have largely been successful, but have relied on translocating species in trophic order from prey to predator. However, bottom-up community reintroductions are not always possible. Round Island supports the last semi-intact natural reptile community, dominated by intraguild predators. To restore Round Island’s reptile community requires reintroducing threatened reptile prey species, such as the LNG. This project will work with a team including Mauritius government, NGO (Mauritian Wildlife Foundation), UK based partners (Durrell Wildlife Conservation Trust) and ARIES DTP hosts (ZSL and University of Kent) to plan and test a range of alternative reintroduction approaches to establish LNG on Round Island. Methods developed for LNG reintroduction will be globally relevant as practitioners grapple with how to establish prey species where predators remain.
Methodology
Funding Notes
The project has been shortlisted for funding by the ARIES NERC Doctoral Training Partnership (https://www.aries-dtp.ac.uk), with a stipend of £14,777 per annum and a generous training and travel budget.
ARIES is committed to equality & diversity, and inclusion of students of any and all backgrounds. All ARIES Universities have Athena Swan Bronze status as a minimum.
Students with high level numerical skills will be eligible for 3 months of additional stipend after the end of the 3.5 years to take advanced-level courses in branches of environmental sciences related to the project in the first 3-6 months of study.
Shortlisted applicants will be interviewed by ARIES on 26th/27th February 2019, with shortlisting taking place at the University of Kent on the 31st January 2019.
Successful candidates who meet UKRI’s eligibility criteria will be awarded a NERC studentship – in 2018/19 the stipend is £14,777. In most cases, UK and EU nationals who have been resident in the UK for 3 years are eligible for a full award.
We seek a people person, passionate about wildlife conservation, with an interest in reptiles and a strong quantitative background in demographic modelling. The candidate should enjoy periods of fieldwork on a remote tropical island with basic communal living arrangements.
Click here to submit your application by the 8th of January.
If you have any queries please email Rachel McCrea: R.S.McCrea@kent.ac.uk
Supervisors
Dr Rachel McCrea, University of Kent and Dr Emily Dennis, Butterfly Conservation
Other Supervisory Team Members
Professor Byron Morgan, University of Kent
Professor Tom Brereton, Butterfly Conservation
Dr David Roy, Centre for Ecology and Hydrology
Project Summary
Three-quarters of UK butterfly species have declined over the past four decades. Butterflies respond quickly to habitat and climatic change, hence their population status is a valuable biodiversity indicator. Analysis of long-term butterfly monitoring datasets has provided some of the world’s best evidence of the biological impacts of climate change, including major phenological and distribution shifts, evolutionary responses and the impacts of extreme events.
Population trends are primarily assessed at national scales. This project will undertake more detailed analysis across spatial scales (e.g across regions, specific habitats or individual sites) to identify butterfly population responses to major drivers of change. As well as delivering high impact scientific insight, this will underpin more effective conservation, from local land management to strategic planning across regions, including the production of new biodiversity indicators and site level alerts.
National-scale butterfly monitoring will be enhanced by refining survey guidance for threatened species, improving knowledge of butterfly lifespans and furthering methods for assessing species threatened status.
Background
A key feature of statistical models applied to butterflies1,2 involves accounting for seasonal variation in counts, as butterflies emerge throughout the year via one or more broods. Flight period patterns vary geographically, for example emergence can be later further north in the UK3. Seasonal patterns are typically assumed to be fixed across space. Counts from the UK Butterfly Monitoring Scheme (UKBMS) are made under standardised conditions4 to minimise bias due to variation in the probability of detecting individuals.
Project Aim
To better explain butterfly population dynamics during a period of rapid environmental change, to project future changes under scenarios of climate change and to create direct benefits for the conservation of butterflies.
Objectives
Person Specification and Training Opportunities
Applicants should have a good degree in a subject such as statistics, mathematics, or another scientific discipline with a substantial quantitative component. A keen interest in ecology is advantageous.
The student will benefit from being immersed in an established Statistical Ecology @ Kent (SE@K) research group (and its wider collaborators), with training opportunities through National Centre for Statistical Ecology (NCSE) meetings, Academy for PhD Training in Statistics courses and the ability to contribute to the running of specialist quantitative training events lead by SE@K. The student will develop practical skills through field-work and data collection with Butterfly Conservation and will attend ARIES DTP training events to develop essential environmental science skills. The student will have extensive opportunity to present their work to varied communities (wider membership of NCSE, statistical and ecological conferences and organisations currently working with members of SE@K). By spending part of the project with Butterfly Conservation, the student will gain experience of working within a conservation organisation and gain new skills through attending field surveys and QGIS training. The supervisory team will ensure ample opportunity for independent development. On graduating, the student will possess a transferable knowledge of modern methods of data science and statistics which will be particularly applicable for careers in conservation and ecology as well as other applied fields.
Funding
The project has been shortlisted for up to 4 years, with 3.5 years minimum, of funding by the ARIES NERC Doctoral Training Partnership (https://www.aries-dtp.ac.uk) with a stipend of £14,777 per annum and a generous training and travel budget for attending UK-based and international conferences, as well as for time spent visiting Butterfly Conservation.
ARIES is committed to equality & diversity, and inclusion of students of any and all backgrounds. All ARIES Universities have Athena Swan Bronze status as a minimum.
Students with high level numerical skills will be eligible for 3 months of additional stipend after the end of the 3.5 years to take advanced-level courses in branches of environmental sciences related to the project in the first 3-6 months of study.
Shortlisted applicants will be interviewed on 26th/27th February 2019.
Successful candidates who meet UKRI’s eligibility criteria will be awarded a NERC studentship – in 2018/19 the stipend is £14,777. In most cases, UK and EU nationals who have been resident in the UK for 3 years are eligible for a full award.
References
1Dennis, E.B., Morgan, B.J.T., Freeman, S.N., Brereton, T.M. and Roy, D.B. (2016). A generalized abundance index for seasonal invertebrates. Biometrics, 72, 1305-1314.
2Dennis, E.B., Morgan, B.J.T., Brereton, T., Freeman, S.N. and Roy, D.B. (2016). Dynamic models for longitudinal butterfly data. Journal of Agricultural, Biological, and Environmental Statistics, 21, 1-21.
3Roy, D.B. and Asher, J. (2003). Spatial trends in the sighting dates of British butterflies. International Journal of Biometeorology, 47, 188-192.
4Pollard, E. and Yates, T.J. (1993). Monitoring Butterflies for Ecology and Conservation: the British Butterfly Monitoring Scheme. Chapman & Hall, London.
5Matechou, E., Dennis, E.B., Freeman, S.N. and Brereton, T. (2014). Monitoring abundance and phenology in (multivoltine) butterfly species: a novel mixture model. Journal of Applied Ecology, 51, 766-775.
6Bubová, T., Kulma, M., Vrabec, V. and Nowicki, P. (2016). Adult longevity and its relationship with conservation status in European butterflies. Journal of Insect Conservation, 20, 1021-1032.
This is a collaborative project between the University of Kent and the Centre for Environment, Fisheries & Aquaculture Science (Cefas)
Click here to submit your application by the 8th of January.
The project is at the intersection of big data, citizen-science, and sustainable fisheries. The student will provide new analytical tools for fisheries scientists to understand fish distributions, catches, effort, and angling behaviour through development of new statistical methods for the analysis of data collected by the smartphone-app Fishbrain, alongside information from current surveys.
The student will lead the development of state-of-the-art statistical methods on the timely topic of inference from large citizen-science data collected using new technologies. They will develop high-level, highly transferable statistical, programming and data skills, working with large app-derived data-sets and designed surveys using tools such as R, Python and Stan. The work will be presented and communicated to statisticians, fisheries-experts, and policy-makers at national and international conferences and meetings.
As a member of the Statistical Ecology @ Kent group and the National Centre for Statistical Ecology the student will be exposed to the latest developments in the fields of statistics and ecology. As part of the cohort of 80 Cefas PhD students they will interact with scientists and advisors from a diverse range of marine and freshwater sciences.
Through supervision and time visiting Cefas, the student will experience working in a multi-disciplinary science organisation and learn how their research fits into the wider policy context. Their work will be part of an MRF research programme at Cefas, Ball State and Danish Technical Universities, and broader fisheries advice through ICES.
The acquired knowledge and expertise in the topic of citizen-science data collected using new technologies will be of great benefit to the student in their future in academia, government, or industry. Although the models will be motivated by angling, the methods will be much more generally applicable to app-collected data on individual behaviour. The available data-sets are large and require efficient, sophisticated algorithms that fit models in reasonable time. Hence the project will equip the student with valuable skills in the growing areas of big data and data-mining.
Additional information on the project can be found here
ARIES is committed to equality & diversity, and inclusion of students of any and all backgrounds. All ARIES Universities have Athena Swan Bronze status as a minimum.
Students with high level numerical skills will be eligible for 3 months of additional stipend after the end of the 3.5 years to take advanced-level courses in branches of environmental sciences related to the project in the first 3-6 months of study.
Applicants should have a good degree in statistics, mathematics, computer science, or related subjects with a strong numerical component. They should be comfortable working with data and learning new methods, determined, and interested in engaging with the practical applications of their research.
Shortlisted applicants will be interviewed by ARIES on the 26th/27th February 2019, with shortlisting taking place at the University of Kent on the 31st of January.
Successful candidates who meet UKRI’s eligibility criteria will be awarded a NERC studentship – in 2018/19 the stipend is £14,777. In most cases, UK and EU nationals who have been resident in the UK for 3 years are eligible for a full award.
Supervisors
Dr Eleni Matechou and Dr Maria Kalli, University of Kent
David Maxwell and Dr Kieran Hyder, Centre for Environment, Fisheries & Aquaculture Science
Dr Christian Skov, National Institute of Aquatic Resources
Dr Paul Venturelli, Ball State University
The supervisory team brings together multidisciplinary expertise covering statistics, data science, recreational fisheries, app development, monitoring, and policy.
Funding Notes
The project has been shortlisted for up to 4 years, with 3.5 years minimum, of funding by the ARIES NERC Doctoral Training Partnership with a stipend of £14,777 per annum and a generous training and travel budget for attending UK-based and international conferences.
Dates and Location: 7-11 January 2019, University of Kent, Canterbury Campus
Deadline for Applications: (Extended) 5pm on Wednesday 31st October 2018, by emailing advancedtraining@kent.ac.uk with a completed application form
Specifications: We have 30 fully-funded places (inc. travel within the UK and accommodation); priority will be given to NERC-funded PhD students but if spaces remain we are able to offer the funded places to other UK-based PhD students and early-career researchers.
Description:
Within the environmental sector there is currently a shortage of practitioners equipped with the statistical modelling skills to carry out reliable population assessments. Consequently, environmental impact assessments (EIAs) and development mitigation projects often use population assessment protocols that are not fit-for-purpose. The skills shortage arises because (1) recent advances in statistical models for population assessment are largely confined to the academic sector with little penetration to the end-users; and (2) although many postgraduate programmes have a statistical modelling training component, this often fails to expose PhD students to new models in the area and the potential applications these have for conservation practice. This training programme will provide a cohort of PhD students and early career researchers/practitioners with the relevant modelling skills required for a career that involves wildlife population assessment for conservation.
The workshop will focus on ecological questions that arise in conservation practice and use real case study data. Training will include individual-based models, such as capture-recapture, but will also embrace scenarios more frequently used in EIA, such as batch-marked, presence/absence, site occupancy and counts. Applications will include newts, butterflies, birds, bees, beetles, ibex and bats. Each module will be accompanied by a practical computer session using R and each module builds on the last so that delegates build a portfolio of statistical skills.
More detailed information about the workshop timetable and training outcomes is available here.
Trainers: Dr Rachel McCrea, Dr Eleni Matechou, Dr Diana Cole, Richard Griffiths.
The paper Removal models accounting for temporary emigration by Ming Shou, Rachel McCrea, Eleni Matechou , Diana Cole and Richard Griffiths has just been published online early in Biometrics.
Summary:
Removal of protected species from sites scheduled for development is often a legal requirement in order to minimize the loss of biodiversity. The assumption of closure in the classic removal model will be violated if individuals become temporarily undetectable, a phenomenon commonly exhibited by reptiles and amphibians. Temporary emigration can be modeled using a multievent framework with a partial hidden process, where the underlying state process describes the movement pattern of animals between the survey area and an area outside of the study. We present a multievent removal model within a robust design framework which allows for individuals becoming temporarily unavailable for detection. We demonstrate how to investigate parameter redundancy in the model. Results suggest the use of the robust design and certain forms of constraints overcome issues of parameter redundancy. We show which combinations of parameters are estimable when the robust design reduces to a single secondary capture occasion within each primary sampling period. Additionally, we explore the benefit of the robust design on the precision of parameters using simulation. We demonstrate that the use of the robust design is highly recommended when sampling removal data. We apply our model to removal data of common lizards, Zootoca vivipara, and for this application precision of parameter estimates is further improved using an integrated model.
The work presents novel dynamic mixture models for the monitoring of bumblebee populations on an unprecedented geographical scale, motivated by the UK citizen science BeeWalk.
The models allow us for the first time to estimate bumblebee phenology and within-season productivity, defined as the number of individuals in each caste per colony in the population in that year, from citizen science data.
All of these parameters are estimated separately for each caste, giving a means of considerable ecological detail in examining temporal changes in the complex life cycle of a social insect in the wild. Due to the dynamic nature of the models, we are able to produce population trends for a number of UK bumblebee species using the available time-series. Via an additional simulation exercise, we show the extent to which useful information will increase if the survey continues, and expands in scale, as expected.
Bumblebees are extraordinarily important components of the ecosystem, providing pollination services of vast economic impact and functioning as indicator species for changes in climate or land use. Our results demonstrate the changes in both phenology and productivity between years and provide an invaluable tool for monitoring bumblebee populations, many of which are in decline, in the UK and around the world.
From 8th-13th July Byron and Marina attended the International Biometric Conference in Barcelona.
Marina gave a talk on Integrated Population Modelling Incorporating Spatial Information.
Byron gave a talk on Hidden Markov modelling for a multi-species index.
Congratulations to Anita who graduated on the 19th of July 2018 with a PhD in Statistics!