human | Q5 |
P268 | Bibliothèque nationale de France ID | 135958790 |
P227 | GND ID | 1031802304 |
P1960 | Google Scholar author ID | kf8nxJ8AAAAJ |
P269 | IdRef ID | 139365192 |
P213 | ISNI | 0000000033021060 |
P244 | Library of Congress authority ID | n99255362 |
P549 | Mathematics Genealogy Project ID | 93426 |
P4955 | MR Author ID | 267385 |
P8189 | National Library of Israel J9U ID | 987007440133605171 |
P1207 | NUKAT ID | n2012141308 |
n2014093081 | ||
P856 | official website | https://www.uu.nl/staff/JAPHeesterbeek |
P496 | ORCID iD | 0000-0001-8537-6418 |
P3987 | SHARE Catalogue author ID | 524741 |
P214 | VIAF ID | 250662821 |
27237218 | ||
P10832 | WorldCat Entities ID | E39PBJtgXhD3MMh8hmKf9PPYT3 |
P1556 | zbMATH author ID | heesterbeek.hans |
P184 | doctoral advisor | Odo Diekmann | Q77084793 |
P185 | doctoral student | Pieter Trapman | Q102307002 |
Marieke Jesse | Q102433649 | ||
Rampal S. Etienne | Q39954037 | ||
P69 | educated at | Leiden University | Q156598 |
P108 | employer | Utrecht University | Q221653 |
P735 | given name | Hans | Q632842 |
Hans | Q632842 | ||
P6104 | maintained by WikiProject | WikiProject Mathematics | Q8487137 |
P106 | occupation | epidemiologist | Q12765408 |
P5008 | on focus list of Wikimedia project | WikiProject COVID-19 | Q87748614 |
P21 | sex or gender | male | Q6581097 |
Q40520300 | A branching model for the spread of infectious animal diseases in varying environments |
Q53419219 | A brief history of R0 and a recipe for its calculation. |
Q44036743 | A curve of thresholds governs plague epizootics in Central Asia |
Q44367502 | A fully coupled, mechanistic model for infectious disease dynamics in a metapopulation: movement and epidemic duration |
Q46524455 | A heterogeneous population model for contagious bovine pleuropneumonia transmission and control in pastoral communities of East Africa |
Q63880293 | A model for the dynamics of a protozoan parasite within and between successive host populations |
Q81389017 | A model of contagious bovine pleuropneumonia transmission dynamics in East Africa |
Q45462505 | A model of lineage-1 and lineage-2 rinderpest virus transmission in pastoral areas of East Africa |
Q57008313 | A modeling study on the sustainability of a certification-and-monitoring program for paratuberculosis in cattle |
Q27477747 | A new method for estimating the effort required to control an infectious disease |
Q51976568 | A simple model for the within-host dynamics of a protozoan parasite. |
Q43852799 | A simple parasite model with complicated dynamics |
Q46487726 | A stochastic exposure assessment model to estimate vanadium intake by beef cattle used as sentinels for the South African vanadium mining industry |
Q56908734 | Assessing the impact of feline immunodeficiency virus and bovine tuberculosis co-infection in African lions |
Q48798781 | Bernoulli was ahead of modern epidemiology |
Q40742824 | Bluff your way in epidemic models |
Q61976426 | Cardiovascular performance of adult breeding sows fails to obey allometric scaling laws1 |
Q46910679 | Challenges in modelling infectious disease dynamics: preface |
Q58189656 | Changes in disease gene frequency over time with differential genotypic fitness and various control strategies |
Q51168007 | Characterizing the next-generation matrix and basic reproduction number in ecological epidemiology. |
Q54450701 | Classification of temporal profiles of F4+ E. coli shedding and faecal dry matter in experimental post-weaning diarrhoea of pigs. |
Q50705160 | Complex systems. Complexity theory and financial regulation. |
Q33184903 | Daniel Bernoulli's epidemiological model revisited. |
Q49336419 | Detecting plague-host abundance from space: Using a spectral vegetation index to identify occupancy of great gerbil burrows |
Q33639373 | Detection of clinical mastitis with sensor data from automatic milking systems is improved by using decision-tree induction |
Q43859008 | Divide and conquer? Persistence of infectious agents in spatial metapopulations of hosts |
Q61976439 | Does cardiovascular performance of modern fattening pigs obey allometric scaling laws? |
Q35198101 | Dynamics of the plague-wildlife-human system in Central Asia are controlled by two epidemiological thresholds |
Q30380254 | Early epidemiological assessment of the virulence of emerging infectious diseases: a case study of an influenza pandemic. |
Q58998256 | Ecology of Parasite-Host Dynamics: Principles, Theory, and Analysis |
Q59291732 | Effect of Eimeria acervulina infection history on the immune response and transmission in broilers |
Q58964687 | Effect of Herd Characteristics, Management Practices, and Season on Different Categories of the Herd Somatic Cell Count |
Q45903197 | Effects of heterogeneity in infection-exposure history and immunity on the dynamics of a protozoan parasite. |
Q30408647 | Effects of infection-induced migration delays on the epidemiology of avian influenza in wild mallard populations |
Q35624546 | Eight challenges in modelling disease ecology in multi-host, multi-agent systems |
Q51650408 | Elasticity analysis in epidemiology: an application to tick-borne infections. |
Q50944041 | Erratum to: Extending the type reproduction number to infectious disease control targeting contacts between types. |
Q30651731 | Estimating mosquito population size from mark-release-recapture data. |
Q125767707 | Exploring the influence of competition on arbovirus invasion risk in communities |
Q36226981 | Exploring vector-borne infection ecology in multi-host communities: A case study of West Nile virus |
Q44824465 | Extending the type reproduction number to infectious disease control targeting contacts between types. |
Q50665790 | Financial complexity: Accounting for fraud--Response. |
Q34249280 | Heterogeneous shedding of Escherichia coli O157 in cattle and its implications for control |
Q35178798 | How mathematical epidemiology became a field of biology: a commentary on Anderson and May (1981) 'The population dynamics of microparasites and their invertebrate hosts'. |
Q39106428 | How resource competition shapes individual life history for nonplastic growth: ungulates in seasonal food environments. |
Q39932709 | How selection forces dictate the variant surface antigens used by malaria parasites |
Q42059044 | How to estimate the efficacy of periodic control of an infectious plant disease |
Q39975621 | How to find natural reservoir hosts from endemic prevalence in a multi-host population: a case study of influenza in waterfowl |
Q87325147 | How will country-based mitigation measures influence the course of the COVID-19 epidemic? |
Q34557971 | Identifying transmission cycles at the human-animal interface: the role of animal reservoirs in maintaining gambiense human african trypanosomiasis |
Q40435418 | Importance of bird-to-bird transmission for the establishment of West Nile virus |
Q111324938 | Infection dynamics in ecosystems: on the interaction between red and grey squirrels, pox virus, pine martens and trees |
Q28660503 | Infectious disease agents mediate interaction in food webs and ecosystems |
Q31029656 | Integrated mapping of establishment risk for emerging vector-borne infections: a case study of canine leishmaniasis in southwest France |
Q34042777 | Invasion and persistence of infectious agents in fragmented host populations |
Q41401979 | Local persistence and extinction of plague in a metapopulation of great gerbil burrows, Kazakhstan |
Q44988718 | Mapping the basic reproduction number (R₀) for vector-borne diseases: a case study on bluetongue virus |
Q33900329 | Methicillin resistant Staphylococcus aureus ST398 in veal calf farming: human MRSA carriage related with animal antimicrobial usage and farm hygiene |
Q30400112 | Mitigation strategies for pandemic influenza A: balancing conflicting policy objectives |
Q41992259 | Model-consistent estimation of the basic reproduction number from the incidence of an emerging infection |
Q24277713 | Modeling infectious disease dynamics in the complex landscape of global health |
Q31059151 | Nonhomogeneous birth and death models for epidemic outbreak data |
Q112287930 | Nutritional status and prey energy density govern reproductive success in a small cetacean |
Q47242990 | On optimal size and number of reserves for metapopulation persistence |
Q34155650 | On the definition and the computation of the basic reproduction ratio R0 in models for infectious diseases in heterogeneous populations |
Q60506324 | Patterns in intraspecific interaction strengths and the stability of food webs |
Q33828700 | Persistence of livestock associated MRSA CC398 in humans is dependent on intensity of animal contact |
Q36911457 | Postexposure subunit vaccination against chronic enteric mycobacterial infection in a natural host |
Q34494103 | Potential corridors and barriers for plague spread in Central Asia. |
Q58964356 | Prediction of the herd somatic cell count of the following month using a linear mixed effect model |
Q35023869 | Principal climatic and edaphic determinants of Culicoides biting midge abundance during the 2007-2008 bluetongue epidemic in the Netherlands, based on OVI light trap data |
Q47308864 | Quantifying BSE control by calculating the basic reproduction ratio R0 for the infection among cattle |
Q51144070 | Quantifying the dilution effect for models in ecological epidemiology. |
Q42182893 | Quantifying transmission of Campylobacter spp. among broilers |
Q51701189 | Reconciling complexity with stability in naturally assembling food webs. |
Q56930284 | Research on infectious disease dynamics. Introduction |
Q57205295 | Rules of Thumb for Conservation of Metapopulations Based on a Stochastic Winking‐Patch Model |
Q28474269 | Self-interest versus group-interest in antiviral control |
Q52040819 | Stability in real food webs: weak links in long loops. |
Q58189644 | The CHRNE 470del20 mutation causing congenital myasthenic syndrome in South African Brahman cattle: Prevalence, origin, and association with performance traits1 |
Q38425533 | The abundance threshold for plague as a critical percolation phenomenon |
Q46862165 | The assessment of biomarkers in sentinel cattle for monitoring vanadium exposure |
Q42978287 | The basic reproduction number for complex disease systems: defining R(0) for tick-borne infections |
Q52390949 | The basic reproduction ratio for sexually transmitted diseases. Part 2. Effects of variable HIV infectivity. |
Q52436387 | The basic reproduction ratio for sexually transmitted diseases: I. Theoretical considerations. |
Q34006711 | The changing incidence of dengue haemorrhagic fever in Indonesia: a 45-year registry-based analysis |
Q51652282 | The computation of R0 for discrete-time epidemic models with dynamic heterogeneity. |
Q33856584 | The construction of next-generation matrices for compartmental epidemic models |
Q45233167 | The dynamics of nematode infections of farmed ruminants |
Q33228041 | The effect of DNA repair defects on reproductive performance in nucleotide excision repair (NER) mouse models: an epidemiological approach |
Q60029443 | The effect of behavioural change on the prediction of R0 in the transmission of AIDS |
Q33267275 | The effectiveness of contact tracing in emerging epidemics |
Q33742849 | The ideal reporting interval for an epidemic to objectively interpret the epidemiological time course |
Q77767400 | The metapopulation dynamics of an infectious disease: tuberculosis in possums |
Q51935812 | The minimum effort required to eradicate infections in models with backward bifurcation. |
Q46747677 | The public health implications of farming cattle in areas with high background concentrations of vanadium. |
Q52405661 | The saturating contact rate in marriage- and epidemic models. |
Q51946664 | The type-reproduction number T in models for infectious disease control. |
Q72150423 | Threshold quantities for helminth infections |
Q46878522 | Vector-borne diseases and the basic reproduction number: a case study of African horse sickness |
Q35980070 | Wild birds and increased transmission of highly pathogenic avian influenza (H5N1) among poultry, Thailand |
Q77084793 | Odo Diekmann | doctoral student | P185 |