| Identifying trends in the use of domestic appliances from household electricity consumption measurements S Firth, K Lomas, A Wright, R Wall Energy and buildings 40 (5), 926-936, 2008 | 448 | 2008 |
| A simple model of PV system performance and its use in fault detection SK Firth, KJ Lomas, SJ Rees Solar energy 84 (4), 624-635, 2010 | 330 | 2010 |
| Central heating thermostat settings and timing: building demographics M Shipworth, SK Firth, MI Gentry, AJ Wright, DT Shipworth, KJ Lomas Building Research & Information 38 (1), 50-69, 2010 | 318 | 2010 |
| Who rebounds most? Estimating direct and indirect rebound effects for different UK socioeconomic groups M Chitnis, S Sorrell, A Druckman, SK Firth, T Jackson Ecological Economics 106, 12-32, 2014 | 316 | 2014 |
| Turning lights into flights: estimating direct and indirect rebound effects for UK households M Chitnis, S Sorrell, A Druckman, SK Firth, T Jackson Energy policy 55, 234-250, 2013 | 316 | 2013 |
| Targeting household energy-efficiency measures using sensitivity analysis SK Firth, KJ Lomas, AJ Wright Building Research & Information 38 (1), 25-41, 2010 | 316 | 2010 |
| Pre-installation challenges: classifying barriers to the introduction of smart home technology L Oliveira, A May, V Mitchell, M Coleman, T Kane, S Firth Loughborough University, 2015 | 284 | 2015 |
| National survey of summertime temperatures and overheating risk in English homes A Beizaee, KJ Lomas, SK Firth Building and Environment 65, 1-17, 2013 | 240 | 2013 |
| The nature of domestic electricity-loads and effects of time averaging on statistics and on-site generation calculations A Wright, S Firth Applied Energy 84 (4), 389-403, 2007 | 224 | 2007 |
| Embodied and operational energy for new-build housing: A case study of construction methods in the UK CR Iddon, SK Firth Energy and Buildings 67, 479-488, 2013 | 207 | 2013 |
| Modeling occupant behavior in buildings S Carlucci, M De Simone, SK Firth, MB Kjærgaard, R Markovic, ... Building and Environment 174, 106768, 2020 | 185 | 2020 |
| Context, control and the spillover of energy use behaviours between office and home settings C Littleford, TJ Ryley, SK Firth Journal of Environmental Psychology 40, 157-166, 2014 | 140 | 2014 |
| How are UK homes heated? A city-wide, socio-technical survey and implications for energy modelling T Kane, SK Firth, KJ Lomas Energy and Buildings 86, 817-832, 2015 | 116 | 2015 |
| A data management platform for personalised real-time energy feedback D Murray, J Liao, L Stankovic, V Stankovic, R Hauxwell-Baldwin, C Wilson, ... 8th International Conference on Energy Efficiency in Domestic Appliances and …, 2015 | 114 | 2015 |
| Investigating CO2 emission reductions in existing urban housing using a community domestic energy model SK Firth, KJ Lomas | 74 | 2009 |
| Challenges for capturing and assessing initial embodied energy: a contractor’s perspective PJ Davies, S Emmitt, SK Firth Construction Management and Economics 32 (3), 290-308, 2014 | 65 | 2014 |
| Information, communication and entertainment appliance use—Insights from a UK household study M Coleman, N Brown, A Wright, SK Firth Energy and Buildings 54, 61-72, 2012 | 64 | 2012 |
| Smart homes, control and energy management: How do smart home technologies influence control over energy use and domestic life? T Hargreaves, R Hauxwell-Baldwin, M Coleman, C Wilson, L Stankovic, ... ECEEE-2015, 2015 | 57 | 2015 |
| Life-cycle assessment of a 100% solar fraction thermal supply to a European apartment building using water-based sensible heat storage A Simons, SK Firth Energy and Buildings 43 (6), 1231-1240, 2011 | 57 | 2011 |
| Occupant behaviour modelling in domestic buildings: the case of household electrical appliances S Yilmaz, SK Firth, D Allinson Journal of Building Performance Simulation 10 (5-6), 582-600, 2017 | 50 | 2017 |
