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Variation in Water Demand Responsiveness to Utility Policies and Weather: A Latent-Class Model

Janine Stone

Butte Hall 603, California State University, Chico, CA 95929-0430, USA

E-mail Address: jmstone@csuchico.edu

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Christopher Goemans

Clark B-312, Colorado State University, Fort Collins, CO 80523, USA

E-mail Address: cgoemans@colostate.edu

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, and

Marco Costanigro

Clark B-326, Colorado State University, Fort Collins, CO 80523, USA

E-mail Address: marco.costanigro@colostate.edu

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https://doi.org/10.1142/S2382624X19500061Cited by:3 (Source: Crossref)

Abstract

Water utilities use demand-side management (DSM) policies to incentivize conservation during shortages. However, because utilities often use DSM policies for the first time during drought, it may be difficult to determine the extent to which policy responsiveness relates to an overall conservation culture, and short-term policy responsiveness may not be generalizable to non-drought periods. This research evaluates the impact of drought and utility policies using 10 years of household-level panel data in the first known application of a fixed-effects, latent-class model [Deb, P and PK Trivedi (2013). Finite mixture for panels with fixed effects. Journal of Econometric Methods, 2(1), 35–51] to water demand data. This flexible estimation approach identifies heterogeneity in policy responsiveness over time as it relates to drought conditions and changes in the utility’s billing structure. Two classes of water demand are identified — one associated with responsiveness to weather and a second with responsiveness to policies. In the class of water demand associated with weather, households are less sensitive to policy changes but exhibit increased sensitivity to precipitation both when the utility is actively promoting conservation (during severe drought) and in post-drought years. Implications for long-term effectiveness of utility conservation policies are discussed.

Keywords:

References

Adamowicz, W and PC Boxall [2002] Understanding heterogeneous preferences in random utility models: A latent class approach. Environmental and Resource Economics, 23(4), 421–446. Crossref, Google Scholar
Aitkin, M and D Rubin [1985] Estimation and hypothesis testing in finite mixture models. Journal of the National Statistical Society, 47, 67–75. Google Scholar
Arbués, F, I Villanúa and R Barberán [2010] Household size and residential water demand: An empirical approach. Australian Journal of Agricultural and Resource Economics, 54(1), 61–80. Crossref, Google Scholar
Arbués, F, MA Garcıa-Valiñas and R Martınez-Espiñeira [2003] Estimation of residential water demand: A state-of-the-art review. The Journal of Socio-Economics, 32(1), 81–102. Crossref, Google Scholar
Bago d’Uva, T [2005] Latent class models for use of primary care: Evidence from a British panel. Health Economics 14(9), 873–892. Crossref, Google Scholar
Bernedo, M, PJ Ferraro and M Price [2014] The persistent impacts of norm-based messaging and their implications for water conservation. Journal of Consumer Policy, 37(3), 437–452. Crossref, Google Scholar
Binet, ME and PM Carlevaro [2014] Estimation of residential water demand with imperfect price perception. Environmental and Resource Economics, 59, 561–581. Crossref, Google Scholar
Brennan, D, S Tapsuwan and G Ingram [2007] The welfare cost of urban outdoor water restrictions. The Australian Journal of Agricultural and Resource Economics, 51, 243–261. Crossref, Google Scholar
Deb, P and PK Trivedi [2002] The structure of demand for health care: Latent class versus two-part models. Journal of Health Economics, 21(4), 601–625. Crossref, Google Scholar
Deb, P and PK Trivedi [2013] Finite mixture for panels with fixed effects. Journal of Econometric Methods, 2(1), 35–51. Crossref, Google Scholar
Gaudin, S [2006] Effect of price information on residential water demand. Applied Economics, 38(4), 383–393. Crossref, Google Scholar
Goemans, C, M Costanigro and J Stone [2012] The interaction of water restriction and pricing policies: Econometric, managerial and distributional implications. Journal of Natural Resources Policy Research, 4(1), 61–77. Crossref, Google Scholar
Grafton, RQ, MB Ward, H To and T Kompas [2011] Determinants of residential water consumption: Evidence and analysis from a 10-country household survey. Water Resources Research, 47(8), W08537. Crossref, Google Scholar
Haber, S, C Singleton and P Grindrod [2016] Analysis and clustering of residential customers energy behavioral demand using smart meter data. IEEE Transactions on Smart Grid, 7(1), 134–144. Google Scholar
Hewitt, JA and WM Hanemann [1995] A discrete/continuous choice approach to residential water demand under block rate pricing. Land Economics, 71(2), 173–192. Crossref, Google Scholar
Howe, CH and C Goemans [2007] Manager to manager — The simple analytics of demand hardening. Journal-American Water Works Association, 99(10), 24–25. Crossref, Google Scholar
Ito, K [2014] Do consumers respond to marginal or average price? Evidence from nonlinear electricity pricing. The American Economic Review, 104(2), 537–563. Crossref, Google Scholar
Jones, CV and JR Morris [1984] Instrumental price estimates and residential water demand. Water Resources Research, 20(2), 197–202. Crossref, Google Scholar
Jorgensen, B, M Graymore and K O’Toole [2009] Household water use behavior: An integrated model. Journal of Environmental Management, 91(1), 227–236. Crossref, Google Scholar
Kenney, DS, RA Klein and MP Clark [2004] Use and effectiveness of municipal water restrictions during drought in Colorado. Journal of the American Water Resources Association, Paper 03072, 77–87. Crossref, Google Scholar
Kenney, DS, C Goemans, R Klein, J Lowrey and K Reidy [2008] Residential water demand management: Lessons from Aurora, Colorado. Journal of the American Water Resources Association, 44(1), 192–207. Crossref, Google Scholar
Larson, KL, C Polsky, P Gober, H Chang and V Shandas [2013] Vulnerability of water systems to the effects of climate change and urbanization: A comparison of Phoenix, Arizona and Portland, Oregon (USA). Environmental Management, 52(1), 179–195. Crossref, Google Scholar
Liebman, JB and RJ Zeckhauser (2004). Schmeduling. Working paper, Harvard University and NBER. www.hks.harvard.edu/jeffreyliebman/schmeduling.pdf (10 January 2017). Google Scholar
Loughran, DS and J Kulick [2004] Demand-side management and energy efficiency in the United States. The Energy Journal, 25(1), 19–43. Crossref, Google Scholar
Marzano, R, C Rougé, P Garrone, L Grilli, JJ Harou and M Pulido-Velazquez [2018] Determinants of the price response to residential water tariffs: Meta-analysis and beyond. Environmental Modeling and Software, 101, 236–248. Crossref, Google Scholar
Muthén, B and W Shedden [1999] Finite mixture modeling with mixture outcomes using the EM algorithm. Biometrics, 55(2), 463–469. Crossref, Google Scholar
Nataraj, S and W Hanemann [2011] Does marginal price matter? A regression continuity approach to estimating water demand. Journal of Environmental Economics and Management, 61(2), 198–212. Crossref, Google Scholar
Nieswiadomy, ML and DJ Molina [1991] A note on price perception in water demand models. Land Economics, 67(3), 352–359. Crossref, Google Scholar
Nieswiadomy, ML [1992] Estimating urban residential water demand: Effects of price structure, conservation, and education. Water Resources Research, 28(3), 609–615. Crossref, Google Scholar
Nordin, JA [1976] A proposed modification of Taylor’s demand analysis: Comment. The Bell Journal of Economics, 7(2), 719–721. Crossref, Google Scholar
Olmstead, SM, MW Hanemann and RN Stavins [2007] Water demand under alternative price structures. Journal of Environmental Economics and Management, 54(2), 181–198. Crossref, Google Scholar
Olmstead, SM and RN Stavins [2009] Comparing price and non-price approaches to urban water conservation. Water Resources Research, 45(4), 181–198. Crossref, Google Scholar
Pérez-Urdiales, M, MA García-Valiñas and R Martínez-Espiñeira [2014] Responses to changes in domestic water tariff structures: A latent class analysis on household-level data from Granada, Spain. Environmental and Resource Economics, 63, 167–191. Crossref, Google Scholar
Provencher, B, KA Baerenklay and RC Bishop [2002] A finite mixture logit model of recreational angling with serially correlated random utility. American Journal of Agricultural Economics, 84(4), 1066–1075. Crossref, Google Scholar
Renwick, ME and RD Green [2000] Do residential water demand-side management policies measure up? An analysis of eight California water agencies. Journal of Environmental Economics and Management, 40(1), 37–55. Crossref, Google Scholar
Sebri, M [2014] A meta-analysis of residential water demand studies. Environmental Development and Sustainability, 16, 499–520. Crossref, Google Scholar
Shin, JS [1985] Perception of price when price information is costly: Evidence from residential electricity demand. Review of Economics Statistics, 67(4), 591–598. Crossref, Google Scholar
Taylor, RG, JR McKean and RA Young [2004] Alternate price specifications for estimating residential water demand with fixed fees. Land Economics, 80(3), 463–475. Crossref, Google Scholar
Wang, CH and H Dong [2017] Responding to the drought: A spatial statistical approach to investigating residential water consumption in Fresno, California. Sustainability, 9(240). Google Scholar
Wedel, M, WS Desarbo, JR Bult and V Ramaswamy [1993] A latent class Poisson regression model for heterogeneous count data. Journal of Applied Econometrics, 8(4), 397–411. Crossref, Google Scholar
Wichman, CJ, LO Taylor and RH von Haefen [2016] Conservation policies: Who responds to price and who responds to prescription? Journal of Environmental Economics and Management, 79, 114–134. Crossref, Google Scholar