LTEK10157U Natural Resource Sampling and Modelling
MSc Programme in Agriculture
MSc Programme in Forest and Nature Management
MSc Programme in Agricultural Development
MSc Programme in Forest Ecosystems, Nature and Society (SUFONAMA)
MSc Programme in Forests and Livelihoods (SUTROFOR)
MSc Programme in Environmental Science
The main objective of the course is to provide students with tools for sampling, modelling and interpreting information on structure and diversity of vegetation cover, land use and production of various products in terrestrial environments. Furthermore, the course aims to enable students to plan and implement minor inventories and field experiments and critically analyse and reflect on the reliability of empirical results. Finally, the course aims to provide students with the basis required for preparing guidelines for sustainable use. Hence, the course contributes to competences needed when doing empirical work within the MSc programmes in Forest and Nature Management, SUFONAMA, SUTROFOR and EnvEuro. The course would also be relevant for students within other programmes, who emphasise management of forest and nature in their curriculum or plan to prepare their MSc thesis within this field.
Course contents in detail
- Measurements in terrestrial environments (forest and nature); for individuals and populations of trees, shrubs, herbs and rare species; for fauna and geophysical site characteristics. The emphasis is on direct measurements but an introduction to applications of remote sensing techniques is given.
- Sampling methods and design, inventory planning and implementation, introduction to experimental design and practice.
- Practical application of statistical methods for analysis of data from inventories and experiments, data management, model choice and model validation.
- Relationships between physical environment (climate, soil, topography) and growth, competition and succession of ecological systems in forest and nature.
- Modelling states and developments of - and relationships between - individuals, populations and systems in forest and nature.
- Models describing volume, biomass and carbon, growth and yield, size distributions, relationships between various measures on individuals (allometric models) and populations.
- Growth models working at various levels of detail: stand growth models, size-class models and individual-tree models.
- Introduction to systems models, including process models, gap models and landscape/ecosystem models.
- Use of quantitative methods, inventory results and models as the basis of sustainable management decisions and natural resource planning.
- Describe principles and procedures applied for measuring typical variables in forest and nature.
- Classify and reflect on sampling strategies typically used in natural resource inventories.
- Describe basic relationships between the biophysical environment, growth of individual organisms and populations, competition between organisms, and succession of ecosystems.
- Show overview of model types used to describe relationships and to model growth and development of individual plants, populations and ecosystems.
- Compare sampling strategies, assess their suitability, and select appropriate strategies for given natural resource contexts.
- Apply principles and methods from basic statistics in typical sampling and modelling situations in terrestrial environments.
- Select suitable model formulations for modelling particular relationships and assess the quality of predictions.
- Apply principles used for measuring and modelling typical variables in forest and nature to new situations.
- Discuss the relevance, reliability, validity and interpretation of empirical data and results obtained in particular contexts.
- Evaluate empirical evidence, put results into perspective and discuss consequences in relation to sustainable management.
Part of the course is based on scientific papers, lecture notes and exercise materials. See Absalon for a list of course literature.
Examples of literature include chapters from:
- Avery, T. E. & H. E. Burkhart. Forest Measurements. McGraw-Hill Inc, New York.
- Bonham, C. D.. Measurements for Terrestrial Vegetation. John Wiley & Sons, New York.
- Buckland, S. T.; D. R. Anderson; K. P. Burnham; J. L. Laake; D. L. Borchers & L. Thomas. Introduction to Distance Sampling. Estimating Abundance of Biological Populations. Oxford University Press, Oxford.
- Franklin, Steven E.. Remote Sensing for Sustainable Forest Management. Lewis Publishers, CRC Press, Boca Raton.
- Vanclay, J. K.. Modelling Forest Growth and Yield. Applications to Mixed Tropical Forests. CAB International, Wallingford.
- Van Laar, A. & A. Akça. Forest Mensuration, Managing Forest Systems, Vol. 13. Springer, Dordrecht.
The course literature will be announced through Absalon. Similarly, all lecture notes, exercise materials and slides will be made available through Absalon.
The distribution of the 12 weekly hours of instruction is: lectures 4 hours, classroom exercises 4 hours, computer exercises 4 hours. The course includes one excursion (approx. 6 hours) in the middle of the course period.
- Project work
- Theory exercises
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- 7,5 ECTS
- Type of assessment
- Written assignment, 12 hours12 hour written assignment. On the day of the examination questions and data are available from 8:00 am. The deadline for submission of the assignment is 8:00 pm.
- All aids allowed
- Marking scale
- 7-point grading scale
- Censorship form
- No external censorship
Several internal examiners
The examination form is the same as for the ordinary examination.
Criteria for exam assesment
See description of learning outcomes
- Course code
- 7,5 ECTS
- Full Degree Master
- 1 block
- Block 3
- Course capacity
- No limit
- Continuing and further education
- Study board
- Study Board of Natural Resources, Environment and Animal Science
- Department of Food and Resource Economics
- Department of Geoscience and Natural Resource Management
- Faculty of Science
- Henrik Meilby (4-6b687068436c697572316e7831676e)