- 17张思维导图, http://chuansong.me/n/1703328241125
- overleaf, statistics cheat sheet
- overleaf, machine learning cheat sheet
- review derivation
- bias-variance
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| https://www.cs.cmu.edu/~epxing/Class/10708-14/lecture.html |
jyfeather
/ minimum_norm.md
Created
June 6, 2016 21:58
% Finding the minimum of a submodular function using Wolfe's min norm point
% algorithm [Fujishige '91]
% Implementation by Andreas Krause (krausea@gmail.com)
%
% function A = sfo_min_norm_point(F,V, opt)
% F: Submodular function
% V: index set
% opt (optional): option struct of parameters, referencing:
%
jyfeather
/ script_EE546_FP
Created
June 1, 2016 18:01
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| Our project is prognostics of Alzheimer's Disease using multimodality data. The purpose is that we want to predict when the AD will happen to the subject, and multimodality data means that we use different data sources including fMRI, PET-scan, demographcis and etc., some of them are static and some of them are time-series. | |
| Thus the input of our project is like this, X matrix. Here X is a spatial temporal matrix. We have P features, and for each subject, each feature is measured at four different time points, baseline, after 12 month, after 24 month, and after 36 month. And we use a linear model to predict the time of AD onset, y, which is our output. The parameter W is in matrix form, since it is multiplied by the spatial temporal data of each subject. | |
| This is our formulation. The first two l2 norm terms are to measure the goodness of fit, especially the second term, it is for censored samples, we prefer that the predicted y should at least be greater than the given y. And the penalty term, nuclear norm i |
jyfeather
/ script_12_02_2015.md
Created
December 2, 2015 07:19
Good morning, everyone. My name is Yan Jin, I am a phd student from industrial engineering department at university of washington. Today I will introduce our project, we call it insight project. My advisor, Dr. Shuai Huang and Dr. Guan Wang from LinkdedIn, and I are working on insight project together.
The insight project is web-based, this is a screen shot of it. It is from a old version, because the current version is under development, I could not get screenshot of newer one.
This is the outline for today. First, I will talk about what this project can do, and then how to do this work, so basically it has two main functionalities, one is from given dataset to answers that users might be interested in, and the other is from natural language questions that users ask to answers, and some tenical details in the end.
Good morning, my name is Yan, and this is my teammate Juan. We will talk about this paper, name is emerging market characteristics and supply network adjustments in internationalizing food supply chains.
This is the outline. First is the introduction to the backgrounds of the problem, then is their framwork to show how they consider this problem. And then Juan will talk the analysis and conclusion parts.
The big background is globalization in food supply network. Globalization makes international food supplier have more oppotunities, for example, Starbucks now is very welcome in China, even Chinese people do not always drink coffee. However, Globalization also makes the design of food supply network more complicated, because some environments in developed countries are different from in developing counties, like the availability of infrastructure and resource.
In this paper, they use EM (emerging markets) to represent developing countries, like BRIC economies, so which
jyfeather
/ script_11_19_2015.md
Created
November 19, 2015 06:35
Now I will talk about the current progress of our project.
These are two objectives of this project. First, we applied SICE method on new dataset, I call it NACC dataset, because it is from prof. Zhou, SICE is used to construct brain connectivity network based on resting fMRI data. After network is built, we compute several network statistics and do the reliability and reproducibility analysis, and compare the result with threshold method, to see if there is advantage for SICE in terms of reliability and reproducibility.
However, this work looks not so nice since we just applied existing methods and made a comparison, we want to improve more, especially in methodology part. And I have another question, what could be our target journal to submit? I will lease these in the end.
This is a big picture of brain network analysis in general. To guide our study, we follow this flow chart to do the analysis. There are five components in this big picture, dataset, ..., connection
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| source | target | value | |
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| 1 | 2 | 1 | |
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| 1 | 10 | 1 |
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| 4d41 544c 4142 2035 2e30 204d 4154 2d66 | |
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| 0f00 0000 ba00 0000 789c ed57 6d0a 8020 | |
| 0c9d 44d1 affe 7893 eed6 1d3a 52b7 3325 |
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| Precentral_L | Precentral_R | Frontal_Sup_L | Frontal_Sup_R | Frontal_Sup_Orb_L | Frontal_Sup_Orb_R | Frontal_Mid_L | Frontal_Mid_R | Frontal_Mid_Orb_L | Frontal_Mid_Orb_R | Frontal_Inf_Oper_L | Frontal_Inf_Oper_R | Frontal_Inf_Tri_L | Frontal_Inf_Tri_R | Frontal_Inf_Orb_L | Frontal_Inf_Orb_R | Rolandic_Oper_L | Rolandic_Oper_R | Supp_Motor_Area_L | Supp_Motor_Area_R | Olfactory_L | Olfactory_R | Frontal_Sup_Medial_L | Frontal_Sup_Medial_R | Frontal_Mid_Orb_L2 | Frontal_Mid_Orb_R2 | Rectus_L | Rectus_R | Insula_L | Insula_R | Cingulum_Ant_L | Cingulum_Ant_R | Cingulum_Mid_L | Cingulum_Mid_R | Cingulum_Post_L | Cingulum_Post_R | Hippocampus_L | Hippocampus_R | ParaHippocampal_L | ParaHippocampal_R | Amygdala_L | Amygdala_R | Calcarine_L | Calcarine_R | Cuneus_L | Cuneus_R | Lingual_L | Lingual_R | Occipital_Sup_L | Occipital_Sup_R | Occipital_Mid_L | Occipital_Mid_R | Occipital_Inf_L | Occipital_Inf_R | Fusiform_L | Fusiform_R | Postcentral_L | Postcentral_R | Parietal_Sup_L | Parietal_Sup_R | Parietal_Inf_L |
|---|
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