Energy policy modeling : United States and Canadian experiences

Alex Cowie As the twentieth century draws to a close, one of our greatest problems is the availability of energy. One way to study the energy problem is to resolve it into four areas; energy demand, energy sources, transportation of energy from sources to demand centers, and the optimal allocation of energy forms to demands. Each of these areas is extremely complex by itself. When efforts are made to tie them together, for example, to produce a National Policy, the complexities are compounded. Another way to study the energy problem, because of its political and so cial consequences, is to resolve it into geographical areas. Individual prov inces of Canada or states of the United States will have their concerns about energy within their geographical boundaries. As producer, consumer, or both, each wants to ensure an energy development program which will work to the maximum benefit of its citizens. Similarly, countries endeavor to pro tect their citizens and undertake energy policies that will assure either a con tinuation of the existing quality of life or - particularly in the case of "Third World" countries - a marked improvement in quality of life. These competing and conflicting goals call for a study which encompasses the whole world. Again, complexity is piled upon complexity. If the prob lem is not yet sufficiently complex, there is an equally complex question of the effect of energy production and use on the ecology.

I Energy Demand Modeling.- References.- 1 The Energy Demand Forecasting System of the National Energy Board.- 1.1 Overview of the Model.- 1.2 Recent Research in the Residential, Commercial, and Industrial Sectors.- 1.3 Applications of the Model.- References.- 2 A Policy Model of Canadian Interfuel Substitution Demands.- 2.1 Introduction.- 2.2 Approach.- 2.3 Model Specifications.- 2.4 Econometric Considerations.- 2.5 Estimation Results.- 2.6 Conclusions.- References.- 3 Inflationary Expectations and the Demand for Capital, Labor, and Energy in Canadian Manufacturing Industries.- 3.1 Introduction.- 3.2 Incorporation of Inflationary Expectations.- 3.3 Methodology and Data.- 3.4 Results and Policy Implications.- 3.5 Conclusions.- References.- 4 The Derived Demand for Energy in the Presence of Supply Constraints.- 4.1 Introduction.- 4.2 A Model of Producer Behavior Subject to Supply Constraints.- 4.3 An Estimated Production Structure for Canadian Manufacturing.- 4.4 Constrained Demand and Two-Stage Translog Model.- 4.5 An Empirical Example.- 4.6 Further Extensions and Applications.- References.- 5 The Residential Demand for Electric Energy and Natural Gas in Canada.- 5.1 Introduction.- 5.2 The Model.- 5.3 Estimation.- 5.4 Results and Interpretation.- 5.5 Conclusions.- References.- 6 An Econometric Model of Alberta Electricity Demand.- 6.1 Introduction.- 6.2 Electricity Prices.- 6.3 Residential Sector.- 6.4 Commercial Sector.- 6.5 Industrial Sector.- 6.6 Conclusion.- References.- 7 A Model for Forecasting Passenger Car Gasoline Demand.- 7.1 Introduction.- 7.2 New Car Sales.- 7.3 Market Share Equations.- 7.4 Probabilities of Survival.- 7.5 Estimation of Mileage Traveled.- 7.6 Fuel Economies and Urban/Nonurban Travel Split.- 7.7 Applications of the Model.- References.- II Energy Supply Modeling.- References.- 8 Choosing the Overall Size of the Strategic Petroleum Reserve.- 8.1 Introduction and Background.- 8.2 The Limitations of Cost-Benefit Analysis.- 8.3 A Parametric Bimatrix Game.- 8.4 Reserve Size and Embargo Length.- 8.5 Some Numerical Results.- 8.6 Conclusions.- 8.7 Post Scriptum.- References.- 9 Economic Modeling of Energy Supply from Burning Wood Wastes at British Columbia Pulp and Paper Mills.- 9.1 Introduction.- 9.2 Description of the Model.- 9.3 Evaluating the Economics of Fossil Fuel Replacement.- 9.4 Evaluating the Economics of Electricity Generation.- 9.5 Energy Pricing and Wood Waste Supply.- 9.6 Conclusions.- References.- 10 Simulation of Tar Sands Mining Operations.- 10.1 Introduction.- 10.2 Historical Background.- 10.3 Technical Background.- 10.4 Simulation Effort.- 10.5 Selection of Mining Equipment.- 10.6 Appendix A.- 10.7 Appendix B.- 10.8 Addendum (October 30, 1978).- 11 A Model of Energy Supply from Western Canada.- 11.1 Introduction.- 11.2 Structure of the Model.- 11.3 Illustrative Model Solutions and Comparative Statics.- 11.4 Concluding Remarks.- References.- 12 The Incorporation of New Technologies in Energy Supply Estimation.- 12.1 Introduction.- 12.2 Scope of the Approach.- 12.3 The Model.- 12.4 Observations on the Model.- References.- III Coal and Transportation Modeling.- References.- 13 Modeling U.S. Coal Supply and Demand.- 13.1 Introduction.- 13.2 Coal in Transition Project.- 13.3 Coal Development Scenarios.- 13.4 Model Results.- 13.5 Assessment of Energy Infrastructure Requirements.- References.- 14 The Transport of Energy by Rail.- 14.1 Introduction.- 14.2 Growth of Rail Capacity.- 14.3 Present Activities at CN.- 14.4 Concluding Remarks.- 15 Coal Slurry Pipelines: A Technology Assessment.- 15.1 Technology Assessment and the Role of the OTA.- 15.2 The Slurry Pipelines Study: An Overview.- 15.3 Modeling Techniques Used.- 15.4 The Results.- References.- 16 Costing the Movement of Western Canadian Coal to Thunder Bay: An Incremental Approach.- 16.1 Introduction.- 16.2 Systems Analysis.- 16.3 Tariff Schedules and Analysis.- 16.4 Policy Implications.- References.- 17 Simulation Modeling of Coal Terminals.- 17.1 Justification for Simulation Modeling.- 17.2 Modeling Considerations at Coal Terminals.- 17.3 Case Study: Richards Bay, South Africa.- 17.4 Conclusion.- 18 A Short Run Model of the World Petroleum Network Based on Decomposition.- 18.1 Introduction.- 18.2 Overall Description of Martinet.- 18.3 Computational Improvements.- Reference.- IV The Problems and Interactions of Energy, Environment, and Conservation.- References.- 19 Projections of Solar Energy Utilization: A Guide to Federal Planning.- 19.1 Introduction.- 19.2 Capturing the Dynamics of the Solar Transition: The Spurr Model.- 19.3 The Buildings Components: An Example.- 19.4 Summary of Projections of Solar Energy Utilization.- References.- 20 Modeling the Economic and Environmental Impacts of Alternative Electric Utility Futures.- 20.1 Introduction.- 20.2 The Utility Simulation Model.- 20.3 Applications of the Modeling and its Results.- 20.4 Usefulness of the Integrated Approach to Modeling.- References.- 21 Systems Approach to Assessing Electricity Conservation Initiatives.- 21.1 Introduction.- 21.2 The Rate Simulation Model.- 21.3 Concepts of Technological Modeling.- 21.4 Results of Applying the Model to Alternative Rate Structures.- References.- 22 Saving Half of California's Energy and Peak Power in Buildings and Appliances.- 22.1 Overview.- 22.2 Case Studies: Optimized Buildings and Appliances.- References.

Alex Cowie As the twentieth century draws to a close, one of our greatest problems is the availability of energy. One way to study the energy problem is to resolve it into four areas: energy demand, energy sources, transportation of energy from sources to demand centers, and the optimal allocation of energy forms to demands. Each of these areas is extremely complex by itself. When efforts are made to tie them together, for example, to produce a National Policy, the complexities are compounded. Another way to study the energy problem, because of its political and social consequences, is to resolve it into geographical areas. Individual provinces of Canada or states of the United States will have their concerns about energy within their geographical boundaries. As producer, consumer, or both, each wants to ensure an energy development program which will work to the maximum benefit of its citizens. Similarly, countries endeavor to protect their citizens and undertake energy policies that will assure either a continuation of the existing quality of life or - particularly in the case of "Third World" countries - a marked improvement in quality of life. These competing and conflicting goals call for a study which encompasses the whole world. Again, complexity is piled upon complexity. If the prob lem is not yet sufficiently complex, there is an equally complex question of the effect of energy production and use on the ecology.

I The Process of Energy Policy Modeling References.- 1 Why should Energy Models Form a Significant Policy Input in an Uncertain Political World?.- References.- 2 Crash Mode Modeling: Analyzing the National Energy Plan.- 2.1 The Crash Mode.- 2.2 Positive and Negative Modeling Experiences.- 2.3 Epilogue.- 3 The Evaluation of Sponsored Research in Energy Storage.- 3.1 Introduction.- 3.2 Prioritization.- 3.3 National Techno-Economic Energy Models.- References.- 4 A Dynamic Welfare Equilibrium Framework for Projecting Energy Futures.- 4.1 Introduction and Background.- 4.2 Model Description.- 4.3 Summary.- References.- 5 Panel Discussion on Important Canadian Energy Decisions for the 1980s and Beyond.- Questions.- Prepared Statement.- Questions.- II National and Regional Energy Modeling Concepts and Methods References.- 6 A Survey of Some Energy Policy Models.- 6.1 Introduction.- 6.2 Brief Descriptions of Some Major U.S. Energy Policy Models.- 6.3 Brief Descriptions of Some Major Canadian Energy Policy Models.- References.- 7 The Brookhaven Energy System Optimization Model: Its Variants and Uses.- 7.1 Introduction.- 7.2 The Brookhaven Energy System Optimization Model (BESOM).- 7.3 The Brookhaven Time-Stepped Energy System Optimization Model (TESOM).- 7.4 The Market Allocation Model (MARKAL).- References.- 8 An Integrated Forecasting Model: A Progress Report.- 8.1 Introduction.- 8.2 Design and Definition of the Model.- 8.3 The Integrated Forecasting Model.- 8.4 Thumbnail Sketches of Sub-Models Provided.- 8.5 Results.- 8.6 Summary and Future Directions.- References.- 9 Network Based Regional Energy Planning Models: An Evolutionary Expose.- 9.1 Introduction.- 9.2 Network Mapping of Supply and Demand.- 9.3 Network Representation of Supply - Distribution System.- 9.4 Investments in New Capacity.- 9.5 Typical Convex Cost Production Function.- 9.6 Summary and Conclusions.- References.- 10 The Alberta Energy Resources Allocation Model.- 10.1 Rationale and Basic Concepts.- 10.2 Model Structure and Data Base.- 10.3 Energy Resource Supply and Prices.- 10.4 Energy Demands.- 10.5 Process Economic Methodology.- 10.6 External Factors.- 10.7 Reference Case Results.- 10.8 Conclusion.- References.- 11 An Alberta Energy Planning Model.- 11.1 Model Overview.- 11.2 A Basic Supply Model.- 11.3 The Basic Model with Variable Demand.- 11.4 An Alternative Approach Using End Use Demand.- 11.5 Interfuel Substitution.- 11.6 An Initial Model.- References.- 12 Time Horizons in Energy Planning Models.- 12.1 Introduction.- 12.2 Procedures for Reducing End Effects.- 12.3 Qualitative Conclusions.- 12.4 Application to Manne's ETA Model.- 12.5 Summary and Recommendations.- References.- 12a Appendix.- 13 How should We Compare Forecasting Models When They Differ?.- 13.1 Introduction.- 13.2 Ingredients of Comparison.- 13.3 An Example: Three Competing Models for Forecasting National Gas Exploration and Discovery.- 13.4 Evaluation of the Three Models.- 13.5 Concluding Remarks.- References.- 14 Panel Discussion on the Future of National Energy Modeling.- Questions.- III The Canadian-United States Gas Pipeline References.- 15 Canadian Perspectives on the Alaska Highway Pipeline: Modeling the Alternatives.- 15.1 The Alaska Highway Pipeline in Context.- 15.2 Economic Evaluation of Alternative Pipeline Sizes and Pressures.- 15.3 Evaluating the Costs and Benefits.- 15.4 What Next?.- 15.5 Modeling Postscript.- References.- 15a Appendix.- 15.A.1 General Description of the Models Used.- 15.A.2 Equations, Data, and Procedures.- References.- 16 Analyzing Alaskan Gas Distribution Options.- 16.1 Introduction.- 16.2 Overview of PIES.- 16.3 Scenario Specifications.- References.- IV The Problems of Financing Energy Development Projects References.- 17 Financing Canadian Energy to 1990: Some Supply Side Constraints.- 17.1 Introduction.- 17.2 OPEC and the United States.- 17.3 U.S. Energy Policy.- 17.4 The Canadian Energy Scene - A Policy Update.- 17.5 Energy Trade.- 17.6 The Economic Scenario and Energy Finances.- 17.7 The Demand for Energy Finance.- 17.8 The Impact of the Energy Sector on Financial Markets.- 17.9 Funding Practices by Energy Borrowers.- 17.10 Domestic and Foreign Savings Sources.- 17.11 Foreign Financing and the Balance of Payments.- 17.12 Size and Risk Considerations.- 17.13 Project Financing.- 17. 14 Conclusions.- References.- 18 The Demand for Funds for Energy Investment in Canada.- 18.1 Introduction.- 18.2 Capital Investment in Canada Since the Mid-1950s.- 18.3 Investment Forecasts.- 18.4 Some Methodological Considerations.- 18.5 Financing Energy Investment.- 18.6 Summary.- References.- 19 Potential Capital Cost and Financing Required for Canadian Energy Projects.- 19.1 Introduction.- 19.2 Investments of Electrical Utilities.- 19.3 Petroleum Industry Investment.- 19.4 Financing of the Petroleum Industry.- 19.5 Major Project Financing.- 19.6 Pipeline Financing.- References.