A negative spatial correlation natural example is the way passengers take seats in public transport. They tend to try to sit away from each other with even spacing.
I'm working on my final paper about Spatial Econometrics and your explanation helped me a lot! But I think it's worth explaining the contiguity criterion: I'm used to using the Queen criterion instead of the Rook, and it confused me a lot.
A potential example of negative spatial correlation - the location of retail stores? If there is a retail store from a chain that isn't highly correlated, the surrounding area probably has a lower rate of retail stores?
The answer for the future: Point 1 has 2 direct neighbours: 2, 5 Point 2 has 3 direct neighbours: 1,3,6 Point 3 has 3 direct neighbours: 2,7,4 Point 4 has 2 direct neighbours: 3,8 => 10 neighbours because of the symmetry: 2*10=20
Great video! but you didn't answer the initial question.. what is the Moran's I for the 2016 election? My home city of NYC has a negative Moran's I - the poorest county in New York State (Bronx) borders on the richest (Manhattan). Every town in Queens houses a different ethnic group.
Your video is very helpful. Woud you mind translating the video and uploading it to a Chinese video website? Because we can’t use UA-cam in China, I hope my friends can learn from it too.
thank you so much for this video! you're a fantastic teacher. I do have one question: is it possible to end up with a positive, but small value for Moran's I that is statistically significant? if so, is there a difference in how you would interpret a larger positive value versus a smaller positive value if both are statistically significant?
Unless I don't know what borders are, I believe the I for the 2016 election is about 0.317, so pretty strongly physically correlated. This is using the naive weighting average above which is like the L_0 norm or something.
How would you recommend computing Morans I for Vectors with values from [0,1]? My first idea was to just subtract x_i with x_mean and take the length of that vector. The problem here is, that its not possible to get a negative value for the length, which leads into getting bad value to interpret. Second idea, is to just compute Morans I for every entry in our vector independent from another and taking the mean of these. Is there any better way?
I live in FL and Moran's I would be about 0 (that is equal democrats and republicans). How ever, republicans cluster in the center of the state versus the coastline. Micro vs. macro have different results.
Killed it. One of the best explanation of Moran's I I've come across.
A negative spatial correlation natural example is the way passengers take seats in public transport. They tend to try to sit away from each other with even spacing.
The one and only explanation I have come across that actually explains this concept from a spatial perspective.
Instead of just showing formula building the understanding through example......your way of teaching is identical👍👍☺
Thanks :)
you have a teaching gift! thanks for explaining and uploading!
The greatest explanation I’ve ever heard. Respect man.
Huge respect for sharing your precious knowledge making it so approachable
Thanks !
Really great and intuitive explanation of it, thank you! 👍
before watch this video I just understand how to calculate moran i using Python. Now I understand how it works!!
Well Done. I commented before I read any comment. This is a good explanation.
I'm working on my final paper about Spatial Econometrics and your explanation helped me a lot! But I think it's worth explaining the contiguity criterion: I'm used to using the Queen criterion instead of the Rook, and it confused me a lot.
The concepts beyond formula are very interesting which are elaborated perfectly by you, thank you 👍
Thanks!
Thanks for uploading. Very crystal.
Thanks for your words!
This was so incredibly clear, thank you so much!
thanks for the explanation. this is what i was looking for. thanks again.
Thank you so much ur way of teaching ...
Very clear explanation. Thank you!
I was starting with watching Luc Anselin. He might teach something to you, but you teach something to me!
reminds of something in the intersection of Voronoi diagrams + clustering + Sammon's projection
Cool! I'll have to look into those topics
A potential example of negative spatial correlation - the location of retail stores? If there is a retail store from a chain that isn't highly correlated, the surrounding area probably has a lower rate of retail stores?
It's super intuitive.
A negative spatial correlation natural example might be a bunch of mountain peaks/ranges with valleys in between
Good point! Thanks
@@ritvikmath much obliged. Thank you for the clear explanations!
What about the chess board? Would that be a good example of this or am I totally off?
Thanks!
can you use graph to build a deeper understanding?
I have a question about W. I counted 16 adjacent pairs not 20. Would you mind showing which pairs are adjacent so I can arrive at 20?
same , I found 16
The answer for the future:
Point 1 has 2 direct neighbours: 2, 5
Point 2 has 3 direct neighbours: 1,3,6
Point 3 has 3 direct neighbours: 2,7,4
Point 4 has 2 direct neighbours: 3,8
=> 10 neighbours
because of the symmetry: 2*10=20
super clear, very makesense
Great video! but you didn't answer the initial question.. what is the Moran's I for the 2016 election? My home city of NYC has a negative Moran's I - the poorest county in New York State (Bronx) borders on the richest (Manhattan). Every town in Queens houses a different ethnic group.
Your video is very helpful. Woud you mind translating the video and uploading it to a Chinese video website? Because we can’t use UA-cam in China, I hope my friends can learn from it too.
Genius
Thank you so much!
Thanks for sharing
👍👍👍👍
thank you so much for this video! you're a fantastic teacher. I do have one question: is it possible to end up with a positive, but small value for Moran's I that is statistically significant?
if so, is there a difference in how you would interpret a larger positive value versus a smaller positive value if both are statistically significant?
Unless I don't know what borders are, I believe the I for the 2016 election is about 0.317, so pretty strongly physically correlated.
This is using the naive weighting average above which is like the L_0 norm or something.
Nice! Thanks for the info. Curious what it will be for this year.
How would you recommend computing Morans I for Vectors with values from [0,1]?
My first idea was to just subtract x_i with x_mean and take the length of that vector. The problem here is, that its not possible to get a negative value for the length, which leads into getting bad value to interpret. Second idea, is to just compute Morans I for every entry in our vector independent from another and taking the mean of these. Is there any better way?
Thank you
Thanks man...
Please talk about how A/B testing is used in Data science. Thanks
Interesting idea! I will look into it. Thanks!
can you do a video about local moran's i?
Can we report p-value from Moran's I value
that is boss
An example of Morans's I = 0 would be people who like to eat liver or durian fruit.
Good example!
On second thought that is not correct since there is clustering.
I live in FL and Moran's I would be about 0 (that is equal democrats and republicans). How ever, republicans cluster in the center of the state versus the coastline. Micro vs. macro have different results.