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More than 100 pages link to this file. The following list shows the first 100 page links to this file only. A full list is available.
- 20.309:Course Information
- 20.309:Lab Report Guidelines
- 20.309:Safety
- 20.309 Main Page
- Aligning the optical trap
- Beam Expander Example
- Bode plots
- Bode plots and frequency response
- Calculating MSD and Diffusion Coefficients
- Cell Reservations
- Cellular microrheology
- Complex Number Review
- Compound Microscope Example
- Converting Gaussian fit to Rayleigh resolution
- DNA Melting: Model function and parameter estimation by nonlinear regression
- DNA Melting: Processing DNA Melting Data
- DNA Melting: Simulating DNA Melting - Intermediate Topics
- DNA Melting: Using the Basic DNAMelter GUI
- DNA Melting: Using the LockIn DNAMelter GUI
- DNA Melting: Using the Matlab DNAMelter GUI
- DNA Melting II: Using the Matlab DNALockIn GUI
- DNA Melting Part 1: Measuring Temperature and Fluorescence
- DNA Melting Part 2: Lock-in Amplifier and Temperature Control
- DNA Melting Thermodynamics
- DNA melting: Identifying the unknown sample
- Electronics Mini-Lab
- Electronics primer
- Error analysis
- Estimating second order system parameters from noise power spectra using nonlinear regression
- Fall 2010: Problem Set 3
- Fall 2012: Journal Presentations
- Finding and measuring things
- Flat-field correction
- Geometrical Optics
- Geometrical optics and ray tracing
- Impedance Analysis
- Input and output impedance
- Lab Manual:Introduction to electronics
- Lab Manual:Optical Trapping
- Lab Manual: Atomic Force Microscopy (AFM)
- Lab Manual: Limits of Detection
- Lab Manual: Measuring DNA Melting Curves
- Lab Manual: Optical Microscopy
- Lab orientation
- Limits of Detection:Report Requirements
- Limits of Detection: Data Sessions
- Locating objects in a fluorescent microscopic image
- MATLAB: Estimating resolution from a PSF slide image
- MATLAB: Estimating viscoelastic spectrum using Mason's method
- Manta G032 camera measurements
- Matlab: Scalebars
- Measuring biological forces mini-lab
- Measuring optical magnification
- Microscopy report outline
- Nonlinear regression
- Optical Microscopy: Brownian motion and microscopy stability
- Optical Microscopy Data Sheets
- Optical Microscopy Part 1: Brightfield Microscopy
- Optical Microscopy Part 2: Fluorescence Microscopy
- Optical Microscopy Part 3: Resolution, Stability, and Particle Tracking
- Optical Microscopy Part 3: Resolution and Stability
- Optical Microscopy Part 4: Particle Tracking
- Optical Microscopy Week 1: Build a brightfield microscope
- Optical Microscopy Week 3: Experiments
- Optical aberrations
- Optical detectors, noise, and the limit of detection
- Optical resolution
- Optical trap
- Optics Bootcamp
- Physical optics and resolution
- Power spectral density
- Procedure: Diffusion in biological gels
- Procedure: Particle tracking
- Procedure: Peptide-DNA Tethering Assay
- Protocols
- Protocols for cell culture
- Protocols for making microscopy samples
- Real electronics
- Relay Lens Example
- Resource list: DNA melting and PCR
- Resource list: Electronics
- Resource list: Image Enhancement
- Resource list: Image processing
- Resource list: Magnetic Resonance Imaging
- Resource list: Matlab
- Resource list: Microscopy
- Resource list: Optical trapping
- Resource list: Optics
- Resource list: Particle tracking
- Resource list: Suppliers
- Review of probability concepts
- SToNCalculator.m
- Shot noise and centroid finding
- Simulating diffusing microspheres in MATLAB
- Spring 2012 Bioinstrumentation Project Lab
- Super resolution microscopy
- Technical Writing
- Temporary Optics Bootcamp
- Understanding log plots
- Understanding the lock-in amplifier