20.309:Course Information: Difference between revisions
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==Lab Hours and Scheduling== | ==Lab Hours and Scheduling== | ||
The lab will be open approximately 40 hour per week. Students are responsible for scheduling sufficient time in the lab to complete assignments | The lab will be open approximately 40 hour per week. Students are responsible for scheduling sufficient time in the lab to complete assignments before the deadline. Generally, the opening hours will be: | ||
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Revision as of 10:56, 10 August 2007
Lab Hours and Scheduling
The lab will be open approximately 40 hour per week. Students are responsible for scheduling sufficient time in the lab to complete assignments before the deadline. Generally, the opening hours will be:
| Monday | 10:00 AM - 6:00 PM |
| Tuesday | 1:00 AM - 9:00 PM |
| Wednesday | 1:00 AM - 9:00 PM |
| Thursday | 10:00 AM - 6:00 PM |
| Friday | 10:00 AM - 6:00 PM |
You must sign up at least 24 hours before coming to the lab. Use the "LAB SIGNUP" link above in the title bar.
Please also read this Lab Guidelines Document regarding safety, lab notebooks, and other issues.
Lab attendance is mandatory. There will be no make-up labs, except in the unfortunate case of extraordinary circumstances.
Lab Grading Rubric
- Presentation of Data (10 pts.)
- all figures have clear purpose, have a figure number and caption, and are discussed in text
- data plots:
- appropriately chosen/organized (e.g. curves overlaid or compared, when appropriate, correct scales, etc.)
- axes labeled with quantities/units
- quality of data
- appropriately chosen/organized (e.g. curves overlaid or compared, when appropriate, correct scales, etc.)
- no "data dumping" or screen captures (unless explicitly specified)
- Analysis/discussion (10 pts.)
- demonstrates understanding of key concepts/methods
- coherent, logical reasoning, clear thought process
- show key numeric parameters; include important calculations and results
- appropriate data processing applied, described and justified
- draw conclusions supported by the data
- Overall quality (5 pts.)
- report typed, well-organized, length appropriate say what you need to – not more or less
- report requirements met
- sufficient time spent in the lab
- citation of any material that isn't your own (e.g. things you looked up on the web, in literature; data from others in the class; be sure to list with whom you worked on the lab)
Two examples of excellent lab reports are available here and here.
Overview of Laboratory Modules
Electronics
Resistive networks, filters, and op-amp circuits for measurement
During the first part of the course we will focus on electronics. Over a series of labs, we will build several types of commonly used electronic circuits and combine them implement a system for measuring DNA melting curves. This section will also provide an introduction to computer control and data acquisition, including LabVIEW and MATLAB software.
Mechanics
Scanning probe microscopy
We will learn to configure and use "home-built" atomic force microscopes (AFMs) for imaging surfaces with nanometer-scale resolution, conducting sensitive force measurements, and exploring the ultimate detection limits of microcantilevers. Such instruments are essential for investigating the mechanics of single biomolecules, cellular adhesion and modulus, as well as the physical properties of biomaterials. The goal of these labs is to gain hands-on experience with these instruments in the lab and understand the basic principles that they use to achieve exquisite sensitivity.
Optics
Fluorescent microscopy, image processing, and optical traps
Approximately half of the semester is devoted to optical microscopy and imaging. The lectures will cover geometric optics, Fourier optics, and optical instrumentation design, the fundamentals of image processing and 3D microscopy. In the labs, we will build microscopes for white light and fluorescent imaging and apply them to studying cellular mechano-transduction based on particle tracking and immunolabeling. We will also use optical traps for high sensitivity measurements of bacterial flagella torque generation, and get some hands-on experience with two-photon and confocal microscopes.
Grading
- 50%: Written reports for lab modules
You will be working in pairs throughout the semester, but you will be submitting individual lab reports.
- 15%: Oral presentation
You will each give a 12 minute presentation on a selected lab module or a relevant journal paper.
- 15%: Homework assignments
These will include questions related to lecture material, lab modules, and selected journal articles.
- 10%: Lab quizzes
These are intended to help you prepare for the experiment you are performing. The questions will be straightforward and should take about 5 minutes before you begin working on each lab.
- 10%: Oral participation during lectures and laboratory modules
Your participation is essential to learning during the semester. This includes attendance at lectures and your peers' presentations.
