Difference between revisions of "Tutorial 6 - 2010"
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| questions_PDF = Tutorial-6-2010.pdf | | questions_PDF = Tutorial-6-2010.pdf | ||
| questions_text_alt = Tutorial questions | | questions_text_alt = Tutorial questions | ||
| solutions_PDF = | | solutions_PDF = | ||
| solutions_text_alt = Solutions | | solutions_text_alt = Solutions by Elliot Cameron. | ||
| other_instructions = Hand-in at class. | | other_instructions = Hand-in at class. | ||
}} | }} | ||
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#. If you were to construct the Newton interpolating polynomial and estimate the heat capacities at :math:`T = 400` K and :math:`T = 800` K, what answer would you get? Explain. | #. If you were to construct the Newton interpolating polynomial and estimate the heat capacities at :math:`T = 400` K and :math:`T = 800` K, what answer would you get? Explain. | ||
Question 2 [1] | Question 2 [1] | ||
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#. Express :math:`\Delta H_R` as a 5th-order polynomial using the Newton form of the interpolating polynomials. Report your intermediate results in a chart, as shown in the course material. | #. Express :math:`\Delta H_R` as a 5th-order polynomial using the Newton form of the interpolating polynomials. Report your intermediate results in a chart, as shown in the course material. | ||
#. Estimate :math:`\Delta H_R(T=200 \rm ^\circ C)` and :math:`\Delta H_R(T=400 \rm ^\circ C)` using the Newton polynomials. Comment on the results. | #. Estimate :math:`\Delta H_R(T=200 \rm ^\circ C)` and :math:`\Delta H_R(T=400 \rm ^\circ C)` using the Newton polynomials. Comment on the results. | ||
</rst> | </rst> |
Latest revision as of 15:04, 2 November 2010
Due date(s): | 28 October 2010 |
(PDF) | Tutorial questions |
Other instructions | Hand-in at class. |
<rst> <rst-options: 'toc' = False/> <rst-options: 'reset-figures' = False/>
.. |m3| replace:: m\ :sup:`3` .. highlight:: python
.. rubric:: Tutorial objectives: Lagrange and Newton interpolation; due 28 October.
Question 1 [2]
====
Use the heat capacity data in the course slides (slide 5) at :math:`T = [300, 500, 900]` K, with corresponding heat capacities :math:`C_p = [29.85, 30.51, 33.42] \rm J\ mol^{-1}\ K^{-1}`
- . Construct the Lagrange interpolating polynomial of order 2 that passes through all three data points. There is no need to simplify the polynomial.
- . Using this polynomial, compute (i.e. predict) the estimated heat capacity at :math:`T = 400` K and :math:`T = 800` K. Are the predictions reasonable?
- . Create a computer plot that shows your polynomial, over the range :math:`T \in [300, 1600]` K. Superimpose on this plot the 14 data points from slide 5 in the course notes.
Where is the greatest prediction error in your polynomial? Is this expected?
- . If you were to construct the Newton interpolating polynomial and estimate the heat capacities at :math:`T = 400` K and :math:`T = 800` K, what answer would you get? Explain.
Question 2 [1]
====
The heat of reaction for a specific reaction depends on temperature as follows:
======================================= ====== ===== ===== ===== =====
- math:`T \rm[^\circ C]` -250 -200 -100 0 100 300
------ ----- ----- ----- ----- -----
- math:`\Delta H_R \rm[J\ mol^{-1}\ K^{-1}]` 160.0 318.0 699.0 870.0 941.0 1040
======================================= ====== ===== ===== ===== =====
- . Express :math:`\Delta H_R` as a 5th-order polynomial using the Newton form of the interpolating polynomials. Report your intermediate results in a chart, as shown in the course material.
- . Estimate :math:`\Delta H_R(T=200 \rm ^\circ C)` and :math:`\Delta H_R(T=400 \rm ^\circ C)` using the Newton polynomials. Comment on the results.
</rst>