Solar Cell Array Design Handbook (19 results)

hardcover. Condition: Good. Dust Jacket Condition: Good. an ex-Library book in good condition, has usual stamps and stickers on the inside and outside of the book; the original dust jacket is included; the spine of the book is faded due to sun exposure;

Hardcover. Condition: Very Good. No Jacket. May have limited writing in cover pages. Pages are unmarked. ~ ThriftBooks: Read More, Spend Less 2.9.

Hardcover. Condition: Good. No Jacket. Former library book; Pages can have notes/highlighting. Spine may show signs of wear. ~ ThriftBooks: Read More, Spend Less 2.9.

Paperback. Condition: Good. Book shows common (average) signs of wear and use. Binding is still tight. Covers are intact but may be repaired. We have 75,000 books to choose from -- Ship within 24 hours -- Satisfaction Guaranteed!

Hardback, 18.5x25.5cm, 549pp. Very good condition (general light wear; foxed upper edge; offset at front and rear) in good dustwrapper (general wear; several 0.5cm tears; creased front flap). ISBN: 0442268424.

Hardback, 18.5x25.5cm, 549pp. Very good condition (general light wear; sunned and foxed at edges; owner's name penned at ffep; offset at front and rear) in good dustwrapper (general wear; faded at spine; several 1cm closed tears; creased at front flap). ISBN: 0442268424. Pictures available on request.

Condition: Good. Ex research library book. Good condition. Light wear to boards. Content is clean and bright. Light toning to page ends. DJ with some edge wear, a few tears and creasing.

Hardcover. Condition: Good. No Jacket. First Edition. Ex-Library copy with typical library marks and stamps. Dust jacket missing. First edition, first printing. Shelf and handling wear to cover and binding, with general signs of previous use. Secure packaging for safe delivery. 2.9.

Hardcover. Condition: Very Good. Very Good. book.

Condition: New. In.

Condition: New.

Taschenbuch. Condition: Neu. Druck auf Anfrage Neuware - Printed after ordering - I Solar Cell Arrays.- 1 Array Systems.- Array Concepts.- 1¿1. Arrays and Batteries.- 1¿2. Arrays, Panels, Parts, and Components.- 1¿3. Array Types.- 1¿4. The Array as Part of the Power System.- 1¿5. The Array as a System.- 1¿6. Hybrid Systems 6 Historical Developments.- 1¿7. History of Terrestrial Arrays.- 1¿8. History of Space Arrays.- 1 ¿9. The Future of Solar Cell Arrays.- Array Applications.- 1¿10. Terrestrial Applications.- 1¿11. Space Applications.- 1¿12. Power from Space.- Array Systems Performance.- 1¿13. Array Ratings.- 1¿14. Terrestrial Flat-Plate Arrays.- 1¿15. Terrestrial Concentrator Arrays.- 1¿16. Space Flat-Hate Arrays.- 1¿17. Spinning Space Arrays.- 1¿18. Space Concentrator Arrays.- 1¿19. Space Array Orbital Performance.- 2 Array Analysis.- Analytical Concepts.- 2¿1. The Role of Analysis.- 2¿2. Atoms and Electrons.- 2¿3. Electric Charge.- 2¿4. Conductors.- 2¿5. Insulators.- 2¿6. Current.- 2¿7. Electric Field.- 2¿8. Potential and Voltage.- 2¿9. Electrical Circuits.- 2¿10. Sources and Generators.- 2¿11. Current Flow Convection.- 2¿12. Resistance and Resistors.- 2¿13. Ohm¿s Law.- 2¿14. Power.- 2¿15. Energy.- 2¿16. Capacitance and Capacitors.- 2¿17. Magnetism.- 2¿18. Inductance and Inductors.- 2¿19. AC and DC Current.- 2¿20. Impedance.- Circuit Analysis.- 2¿21. Circuit Modelling.- 2¿22. Circuit Simplifications.- 2¿23. Circuit Responses.- 2¿24. Circuit Equations.- 2¿25. Operating Points.- Semiconductors and Solar Cell Models.- 2¿26. Quantum Mechanics.- 2¿27. Semiconductor Materials.- 2¿28. Semiconductor Junctions.- 2¿29. Solar Cell Operation.- 2¿30. Solar Cell Equation.- 2¿31. Solar Cell DC Model.- 2¿32. Distributed Parameter Solar Cell Model.- 2¿33. Analytical Models for Computer Work.- 2¿34. Non-Analytical Computer Models.- 2¿35. Selecting the Proper Model.- 2¿36. Solar Cell AC Model.- 2¿37. Solar Cells in Parallel and Series.- 2¿38. Illuminated Arrays.- 2¿39. Partially Shadowed Cells in Parallel.- 2¿40. Partially Shadowed Cells in Series.- 2¿41. Solar Cell Strings with Shunt Diodes.- 2¿42. Shadowing Factors.- 2¿43. Nonilluminated Array Models.- 2¿44. Blocking Diode Models.- 2¿45. Reverse-Biased Solar Cells.- 2¿46. Power Dissipation in Reverse-Biased Solar Cells.- Array Performance Prediction.- 2¿47. Array Output Analysis.- 2¿48. Sequence of Shifting I¿V Curves.- 2¿49. Calculation of Angle of Incidence.- 2¿50. Calculation of Effective Solar Intensity.- 2¿51. Calculation of Cell and Array I¿V Curves.- Shadow Analysis.- 2¿52. Shadows 84 Thermal Analysis.- Thermal Analysis.- 2¿53. Heat Flow and Temperature.- 2¿54. Heat Transfer by Conduction.- 2¿55. Heat Transfer by Convection.- 2¿56. Heat Transfer by Radiation.- 2¿57. Electrical Heat Transfer Analogy.- 2¿58. Terrestrial Array Operating Temperatures.- Reliability.- 2¿59. Reliability and Failure Rates.- 2¿60. Failure Modes and Effects.- 2¿61. Reliability Models.- Orbital Analysis.- 2¿62. Spacecraft Motion in Orbit.- 2¿63. Simplified Orbit Theory.- 2¿64. Altitude in Elliptic Orbits.- 2¿65. Location in Space.- 2¿66. Illumination of the Orbit Plane.- 2¿67. The Sun Angle.- 2¿68. Solar Eclipses.- 3 Array Design.- Design Concepts.- 3¿1. The Design Process.- 3¿2. Design Phases.- 3¿3. Design Personnel.- 3¿4. Uncertainties and Risks.- 3¿5. Design Optimization.- 3¿6. Design Requirements, Criteria and Interfaces.- 3¿7. Policy Constraints.- 3¿8. Design Review.- 3¿9. Producibility and Cost.- 3¿10. Human Engineering.- Photovoltaic System Design.- 3¿11. Load Profile Development.- 3¿12. Illumination Profile Development.- 3¿13. Preliminary Array Sizing¿Area Method.- 3¿14. Preliminary Array Sizing-Cell Efficiency Method.- 3¿15. Preliminary Array Sizing-Cell Power Method.- Detailed Array Design.- 3¿16. Detailed Array Sizing.- 3¿17. Space Array Configuration Selection.- 3¿18. Number of Required Solar Cells.- 3¿19. Array Layout.- 3¿20. Array Wiring.- 3¿21. Hot Spot Design Considerations.- 3¿22. Designing for Reliability.- 3¿23. High Voltage Design.- Thermal Design.- 3¿24. Temperature Control in Space.- 3¿25. Temperature Control on Earth.- 3¿26. Decreasing Absorptance.- 3¿27. Increasing Emittance.- 3¿28. Increasing Convection.- 3¿29. Improving the Geometry.- 3¿30. Minimizing Eclipse Exit Temperatures.- Radiation Shielding Design.- 3¿31. Solar Cell Radiation Shielding.- 3¿32. Damage-Equivalent Fluence in Orbit.- 3¿33. Shielding Thickness Determination.- 3¿34. Procedure for 1-MeV Fluence Analysis.- 3¿35. Shielding Against Low Energy Protons.- 3¿36. Absorbed Dose in Cover and Adhesive.- Electromagnetic Design.- 3¿37. Electrostatic Shielding.- 3¿38. Magnetic Cleanliness.- 3¿39. Minimizing Magnetic Moments.- 3¿40. Electrostatic Charging Control.- II Array Building Blocks.- 4 Solar Cells.- Photovoltaics.- 4¿1. Solar Cell Devices.- 4¿2. Direct Energy Conversion.- 4¿3. Discovery of the Photovoltaic Effect.- 4¿4. History of Contemporary Silicon Cells.- 4¿5. History of Non-Silicon Cells.- Solar Cell Types.- 4¿6. Solar Cell Classification.- 4 ¿ 7. Classification According to Application.- 4¿8. Classification According to Materials.- 4 ¿9. Classification According to Construction.- 4¿10. Classification According to Optical Features.- 4¿11. Contemporary Silicon Solar Cell Types for Space Use.- 4¿12. Contemporary Silicon Solar Cells for Terrestrial Use.- Electrical Characteristics.- 4¿13. Solar Cell Polarity.- 4¿14. Current-Voltage Characteristics.- 4¿15. Series Resistance.- 4¿16. Shunt Resistance.- 4¿17. Energy Conversion Efficiency.- 4¿18. Curve and Fill Factors.- 4¿19. Effects of Solar Intensity.- 4¿20. Reversible Effects of Temperature.- 4¿21. Temperature Coefficients.- 4¿22. Irreversible Temperature Effects.- 4¿23. High-Intensity, High-Temperature Operation.- 4¿24. Low-Intensity, Low-Temperature Operation.- 4¿25. Reverse Characteristics.- Optical Characteristics.- 4¿26. Effects of Optical Characteristics on Cell Efficiency.- 4¿27. Spectral Response Defined.- 4¿28. Spectral Response of Solar Cells.- Mechanic.

Taschenbuch. Condition: Neu. Neuware -I Solar Cell Arrays.- 1 Array Systems.- Array Concepts.- 1¿1. Arrays and Batteries.- 1¿2. Arrays, Panels, Parts, and Components.- 1¿3. Array Types.- 1¿4. The Array as Part of the Power System.- 1¿5. The Array as a System.- 1¿6. Hybrid Systems 6 Historical Developments.- 1¿7. History of Terrestrial Arrays.- 1¿8. History of Space Arrays.- 1 ¿9. The Future of Solar Cell Arrays.- Array Applications.- 1¿10. Terrestrial Applications.- 1¿11. Space Applications.- 1¿12. Power from Space.- Array Systems Performance.- 1¿13. Array Ratings.- 1¿14. Terrestrial Flat-Plate Arrays.- 1¿15. Terrestrial Concentrator Arrays.- 1¿16. Space Flat-Hate Arrays.- 1¿17. Spinning Space Arrays.- 1¿18. Space Concentrator Arrays.- 1¿19. Space Array Orbital Performance.- 2 Array Analysis.- Analytical Concepts.- 2¿1. The Role of Analysis.- 2¿2. Atoms and Electrons.- 2¿3. Electric Charge.- 2¿4. Conductors.- 2¿5. Insulators.- 2¿6. Current.- 2¿7. Electric Field.- 2¿8. Potential and Voltage.- 2¿9. Electrical Circuits.- 2¿10. Sources and Generators.- 2¿11. Current Flow Convection.- 2¿12. Resistance and Resistors.- 2¿13. Ohm¿s Law.- 2¿14. Power.- 2¿15. Energy.- 2¿16. Capacitance and Capacitors.- 2¿17. Magnetism.- 2¿18. Inductance and Inductors.- 2¿19. AC and DC Current.- 2¿20. Impedance.- Circuit Analysis.- 2¿21. Circuit Modelling.- 2¿22. Circuit Simplifications.- 2¿23. Circuit Responses.- 2¿24. Circuit Equations.- 2¿25. Operating Points.- Semiconductors and Solar Cell Models.- 2¿26. Quantum Mechanics.- 2¿27. Semiconductor Materials.- 2¿28. Semiconductor Junctions.- 2¿29. Solar Cell Operation.- 2¿30. Solar Cell Equation.- 2¿31. Solar Cell DC Model.- 2¿32. Distributed Parameter Solar Cell Model.- 2¿33. Analytical Models for Computer Work.- 2¿34. Non-Analytical Computer Models.- 2¿35. Selecting the Proper Model.- 2¿36. Solar Cell AC Model.- 2¿37. Solar Cells in Parallel and Series.- 2¿38. Illuminated Arrays.- 2¿39. Partially Shadowed Cells in Parallel.- 2¿40. Partially Shadowed Cells in Series.- 2¿41. Solar Cell Strings with Shunt Diodes.- 2¿42. Shadowing Factors.- 2¿43. Nonilluminated Array Models.- 2¿44. Blocking Diode Models.- 2¿45. Reverse-Biased Solar Cells.- 2¿46. Power Dissipation in Reverse-Biased Solar Cells.- Array Performance Prediction.- 2¿47. Array Output Analysis.- 2¿48. Sequence of Shifting I¿V Curves.- 2¿49. Calculation of Angle of Incidence.- 2¿50. Calculation of Effective Solar Intensity.- 2¿51. Calculation of Cell and Array I¿V Curves.- Shadow Analysis.- 2¿52. Shadows 84 Thermal Analysis.- Thermal Analysis.- 2¿53. Heat Flow and Temperature.- 2¿54. Heat Transfer by Conduction.- 2¿55. Heat Transfer by Convection.- 2¿56. Heat Transfer by Radiation.- 2¿57. Electrical Heat Transfer Analogy.- 2¿58. Terrestrial Array Operating Temperatures.- Reliability.- 2¿59. Reliability and Failure Rates.- 2¿60. Failure Modes and Effects.- 2¿61. Reliability Models.- Orbital Analysis.- 2¿62. Spacecraft Motion in Orbit.- 2¿63. Simplified Orbit Theory.- 2¿64. Altitude in Elliptic Orbits.- 2¿65. Location in Space.- 2¿66. Illumination of the Orbit Plane.- 2¿67. The Sun Angle.- 2¿68. Solar Eclipses.- 3 Array Design.- Design Concepts.- 3¿1. The Design Process.- 3¿2. Design Phases.- 3¿3. Design Personnel.- 3¿4. Uncertainties and Risks.- 3¿5. Design Optimization.- 3¿6. Design Requirements, Criteria and Interfaces.- 3¿7. Policy Constraints.- 3¿8. Design Review.- 3¿9. Producibility and Cost.- 3¿10. Human Engineering.- Photovoltaic System Design.- 3¿11. Load Profile Development.- 3¿12. Illumination Profile Development.- 3¿13. Preliminary Array Sizing¿Area Method.- 3¿14. Preliminary Array Sizing-Cell Efficiency Method.- 3¿15. Preliminary Array Sizing-Cell Power Method.- Detailed Array Design.- 3¿16. Detailed Array Sizing.- 3¿17. Space Array Configuration Selection.- 3¿18. Number of Required Solar Cells.- 3¿19. Array Layout.- 3¿20. Array Wiring.- 3¿21. Hot Spot Design Considerations.- 3¿22. Designing for Reliability.- 3¿23. High Voltage Design.- Thermal Design.- 3¿24. Temperature Control in Space.- 3¿25. Temperature Control on Earth.- 3¿26. Decreasing Absorptance.- 3¿27. Increasing Emittance.- 3¿28. Increasing Convection.- 3¿29. Improving the Geometry.- 3¿30. Minimizing Eclipse Exit Temperatures.- Radiation Shielding Design.- 3¿31. Solar Cell Radiation Shielding.- 3¿32. Damage-Equivalent Fluence in Orbit.- 3¿33. Shielding Thickness Determination.- 3¿34. Procedure for 1-MeV Fluence Analysis.- 3¿35. Shielding Against Low Energy Protons.- 3¿36. Absorbed Dose in Cover and Adhesive.- Electromagnetic Design.- 3¿37. Electrostatic Shielding.- 3¿38. Magnetic Cleanliness.- 3¿39. Minimizing Magnetic Moments.- 3¿40. Electrostatic Charging Control.- II Array Building Blocks.- 4 Solar Cells.- Photovoltaics.- 4¿1. Solar Cell Devices.- 4¿2. Direct Energy Conversion.- 4¿3. Discovery of the Photovoltaic Effect.- 4¿4. History of Contemporary Silicon Cells.- 4¿5. History of Non-Silicon Cells.- Solar Cell Types.- 4¿6. Solar Cell Classification.- 4 ¿ 7. Classification According to Application.- 4¿8. Classification According to Materials.- 4 ¿9. Classification According to Construction.- 4¿10. Classification According to Optical Features.- 4¿11. Contemporary Silicon Solar Cell Types for Space Use.- 4¿12. Contemporary Silicon Solar Cells for Terrestrial Use.- Electrical Characteristics.- 4¿13. Solar Cell Polarity.- 4¿14. Current-Voltage Characteristics.- 4¿15. Series Resistance.- 4¿16. Shunt Resistance.- 4¿17. Energy Conversion Efficiency.- 4¿18. Curve and Fill Factors.- 4¿19. Effects of Solar Intensity.- 4¿20. Reversible Effects of Temperature.- 4¿21. Temperature Coefficients.- 4¿22. Irreversible Temperature Effects.- 4¿23. High-Intensity, High-Temperature Operation.- 4¿24. Low-Intensity, Low-Temperature Operation.- 4¿25. Reverse Characteristics.- Optical Characteristics.- 4¿26. Effects of Optical Characteristics on Cell Efficiency.- 4¿27. Spectral Response Defined.- 4¿28. Spectral Response of Solar Cells.- Mechanical Characteristics.- 4¿29. Solar Cell Sizes.

Condition: New. pp. 572.

Paperback. Condition: Brand New. reprint edition. 572 pages. 10.00x7.01x1.30 inches. In Stock.

Paperback. Condition: Like New. Like New. book.

Taschenbuch. Condition: Neu. This item is printed on demand - it takes 3-4 days longer - Neuware -I Solar Cell Arrays.- 1 Array Systems.- Array Concepts.- 1¿1. Arrays and Batteries.- 1¿2. Arrays, Panels, Parts, and Components.- 1¿3. Array Types.- 1¿4. The Array as Part of the Power System.- 1¿5. The Array as a System.- 1¿6. Hybrid Systems 6 Historical Developments.- 1¿7. History of Terrestrial Arrays.- 1¿8. History of Space Arrays.- 1 ¿9. The Future of Solar Cell Arrays.- Array Applications.- 1¿10. Terrestrial Applications.- 1¿11. Space Applications.- 1¿12. Power from Space.- Array Systems Performance.- 1¿13. Array Ratings.- 1¿14. Terrestrial Flat-Plate Arrays.- 1¿15. Terrestrial Concentrator Arrays.- 1¿16. Space Flat-Hate Arrays.- 1¿17. Spinning Space Arrays.- 1¿18. Space Concentrator Arrays.- 1¿19. Space Array Orbital Performance.- 2 Array Analysis.- Analytical Concepts.- 2¿1. The Role of Analysis.- 2¿2. Atoms and Electrons.- 2¿3. Electric Charge.- 2¿4. Conductors.- 2¿5. Insulators.- 2¿6. Current.- 2¿7. Electric Field.- 2¿8. Potential and Voltage.- 2¿9. Electrical Circuits.- 2¿10. Sources and Generators.- 2¿11. Current Flow Convection.- 2¿12. Resistance and Resistors.- 2¿13. Ohm¿s Law.- 2¿14. Power.- 2¿15. Energy.- 2¿16. Capacitance and Capacitors.- 2¿17. Magnetism.- 2¿18. Inductance and Inductors.- 2¿19. AC and DC Current.- 2¿20. Impedance.- Circuit Analysis.- 2¿21. Circuit Modelling.- 2¿22. Circuit Simplifications.- 2¿23. Circuit Responses.- 2¿24. Circuit Equations.- 2¿25. Operating Points.- Semiconductors and Solar Cell Models.- 2¿26. Quantum Mechanics.- 2¿27. Semiconductor Materials.- 2¿28. Semiconductor Junctions.- 2¿29. Solar Cell Operation.- 2¿30. Solar Cell Equation.- 2¿31. Solar Cell DC Model.- 2¿32. Distributed Parameter Solar Cell Model.- 2¿33. Analytical Models for Computer Work.- 2¿34. Non-Analytical Computer Models.- 2¿35. Selecting the Proper Model.- 2¿36. Solar Cell AC Model.- 2¿37. Solar Cells in Parallel and Series.- 2¿38. Illuminated Arrays.- 2¿39. Partially Shadowed Cells in Parallel.- 2¿40. Partially Shadowed Cells in Series.- 2¿41. Solar Cell Strings with Shunt Diodes.- 2¿42. Shadowing Factors.- 2¿43. Nonilluminated Array Models.- 2¿44. Blocking Diode Models.- 2¿45. Reverse-Biased Solar Cells.- 2¿46. Power Dissipation in Reverse-Biased Solar Cells.- Array Performance Prediction.- 2¿47. Array Output Analysis.- 2¿48. Sequence of Shifting I¿V Curves.- 2¿49. Calculation of Angle of Incidence.- 2¿50. Calculation of Effective Solar Intensity.- 2¿51. Calculation of Cell and Array I¿V Curves.- Shadow Analysis.- 2¿52. Shadows 84 Thermal Analysis.- Thermal Analysis.- 2¿53. Heat Flow and Temperature.- 2¿54. Heat Transfer by Conduction.- 2¿55. Heat Transfer by Convection.- 2¿56. Heat Transfer by Radiation.- 2¿57. Electrical Heat Transfer Analogy.- 2¿58. Terrestrial Array Operating Temperatures.- Reliability.- 2¿59. Reliability and Failure Rates.- 2¿60. Failure Modes and Effects.- 2¿61. Reliability Models.- Orbital Analysis.- 2¿62. Spacecraft Motion in Orbit.- 2¿63. Simplified Orbit Theory.- 2¿64. Altitude in Elliptic Orbits.- 2¿65. Location in Space.- 2¿66. Illumination of the Orbit Plane.- 2¿67. The Sun Angle.- 2¿68. Solar Eclipses.- 3 Array Design.- Design Concepts.- 3¿1. The Design Process.- 3¿2. Design Phases.- 3¿3. Design Personnel.- 3¿4. Uncertainties and Risks.- 3¿5. Design Optimization.- 3¿6. Design Requirements, Criteria and Interfaces.- 3¿7. Policy Constraints.- 3¿8. Design Review.- 3¿9. Producibility and Cost.- 3¿10. Human Engineering.- Photovoltaic System Design.- 3¿11. Load Profile Development.- 3¿12. Illumination Profile Development.- 3¿13. Preliminary Array Sizing¿Area Method.- 3¿14. Preliminary Array Sizing-Cell Efficiency Method.- 3¿15. Preliminary Array Sizing-Cell Power Method.- Detailed Array Design.- 3¿16. Detailed Array Sizing.- 3¿17. Space Array Configuration Selection.- 3¿18. Number of Required Solar Cells.- 3¿19. Array Layout.- 3¿20. Array Wiring.- 3¿21. Hot Spot Design Considerations.- 3¿22. Designing for Reliability.- 3¿23. High Voltage Design.- Thermal Design.- 3¿24. Temperature Control in Space.- 3¿25. Temperature Control on Earth.- 3¿26. Decreasing Absorptance.- 3¿27. Increasing Emittance.- 3¿28. Increasing Convection.- 3¿29. Improving the Geometry.- 3¿30. Minimizing Eclipse Exit Temperatures.- Radiation Shielding Design.- 3¿31. Solar Cell Radiation Shielding.- 3¿32. Damage-Equivalent Fluence in Orbit.- 3¿33. Shielding Thickness Determination.- 3¿34. Procedure for 1-MeV Fluence Analysis.- 3¿35. Shielding Against Low Energy Protons.- 3¿36. Absorbed Dose in Cover and Adhesive.- Electromagnetic Design.- 3¿37. Electrostatic Shielding.- 3¿38. Magnetic Cleanliness.- 3¿39. Minimizing Magnetic Moments.- 3¿40. Electrostatic Charging Control.- II Array Building Blocks.- 4 Solar Cells.- Photovoltaics.- 4¿1. Solar Cell Devices.- 4¿2. Direct Energy Conversion.- 4¿3. Discovery of the Photovoltaic Effect.- 4¿4. History of Contemporary Silicon Cells.- 4¿5. History of Non-Silicon Cells.- Solar Cell Types.- 4¿6. Solar Cell Classification.- 4 ¿ 7. Classification According to Application.- 4¿8. Classification According to Materials.- 4 ¿9. Classification According to Construction.- 4¿10. Classification According to Optical Features.- 4¿11. Contemporary Silicon Solar Cell Types for Space Use.- 4¿12. Contemporary Silicon Solar Cells for Terrestrial Use.- Electrical Characteristics.- 4¿13. Solar Cell Polarity.- 4¿14. Current-Voltage Characteristics.- 4¿15. Series Resistance.- 4¿16. Shunt Resistance.- 4¿17. Energy Conversion Efficiency.- 4¿18. Curve and Fill Factors.- 4¿19. Effects of Solar Intensity.- 4¿20. Reversible Effects of Temperature.- 4¿21. Temperature Coefficients.- 4¿22. Irreversible Temperature Effects.- 4¿23. High-Intensity, High-Temperature Operation.- 4¿24. Low-Intensity, Low-Temperature Operation.- 4¿25. Reverse Characteristics.- Optical Characteristics.- 4¿26. Effects of Optical Characteristics on Cell Efficiency.- 4¿27. Spectral Response Defined.- 4¿28. Spectral Response of Solar.

Condition: New. Print on Demand pp. 572 66:B&W 7 x 10 in or 254 x 178 mm Perfect Bound on White w/Gloss Lam.

Condition: New. PRINT ON DEMAND pp. 572.