Constructive Interference

 

I took a walk today at work (I work at a public school district bus depot) and found some great examples of constructive interference. What is constructive interference you might ask? Well, it's responsible for all the colors you are seeing in the water from the pictures above. The water has oil in it which causes it to be iridescent. The oil in the water creates a thin film that is reflecting light not only once, but twice! Once on the top layer of the oil and once on the bottom layer of the oil.

When the two waves are in alignment, the amplitude increases creating constructive interference. As different wavelengths of light hit the oil, they cause varying levels of constructive interference which produces all the colors that we see. So next time you see this occur you can shout to world, "Aha! The beauty of constructive interference!"

Source: Philip Dennison's 2013 Environmental Optics Course Reader

Orbital ATK Antares Launch Explosion

NASA just released hi-def images of the Antares rocket explosion from last year in all its gritty glory. They posted them on Flickr so check it out!

Satellite Imagery

A sense of perspective is unavoidable from 22,000 miles out. Looking down at Earth from that distance — almost three times farther than the diameter of the planet itself — allows a view of the globe as a massive organic system, pulsing with continuous movement. Below, images from the Himawari-8 weather satellite's first official day paint a living portrait of the western Pacific, with Typhoons Chan-hom and Nangka spinning slowly westward. 

Source: New York Times

Mars Crater (Great background image!)

This new image from NASA’s Mars Reconnaissance Orbiter shows an impact crater about 100 feet (30 meters) in diameter that appeared at some time between July 2010 and May 2012.

Space rocks hitting Mars excavate fresh craters at a pace of more than 200 per year, but few new Mars scars pack as much visual punch as one seen in a NASA image released today.

The image from the High Resolution Imaging Science Experiment (HiRISE) camera on NASA’s Mars Reconnaissance Orbiter shows a crater about 100 feet (30 meters) in diameter at the center of a radial burst painting the surface with a pattern of bright and dark tones.

The scar appeared at some time between imaging of this location by the orbiter’s Context Camera in July 2010 and again in May 2012. Based on apparent changes between those before-and-after images at lower resolution, researchers used HiRISE to acquire this new image on November 19, 2013. The impact that excavated this crater threw some material as far as 9.3 miles (15 kilometers).

The Mars Reconnaissance Orbiter Project is managed by NASA’s Jet Propulsion Laboratory, Pasadena, California, for NASA’s Science Mission Directorate, Washington. JPL is a division of the California Institute of Technology in Pasadena. HiRISE is operated by the University of Arizona, Tucson. The instrument was built by Ball Aerospace & Technologies Corp., Boulder, Colorado. Malin Space Science Systems, San Diego, built and operates the Context Camera.

For more information about the Mars Reconnaissance Orbiter, which has been studying Mars from orbit since 2006, visit http://www.nasa.gov/mro.

Source: Guy Webster, Jet Propulsion Laboratory; NASA SciTechDaily

Image: NASA/JPL-Caltech/Univ. of Arizona

Calbuco Thermal Infrared

I think this is one of the cooler images I've collected (even though it didn't get very many instagram likes). From April 27th Landsat 8 6-5-4 false color composite on the left and band 10 on the right. Band 10 is one of the Thermal Infrared bands, so the lighter areas show more heat and darker show less. Even smoke from a volcano gets relatively cool once in the atmosphere.

Pretty cool, right?

Chile Volcano Time Series

Taken from Aqua and Terra Satellites this gif shows the Chile volcano from 4/24-4/27

Calbuco Volcano Chile Imagery

Terra image morning of 4-24-15
Trail of ash is spread out over 100 miles

Aqua image afternoon of  4-24-15

Google Earth Image of Calbuco pre-eruption

The Calbuco volcano in southern Chile has erupted twice in the space of a few hours - having lain dormant for decades.

Footage from the area shows a huge column of lava and ash being sent several kilometres into the air.

The authorities have declared a red alert and evacuated more than 4,000 people within a 20km (12 mile) radius.

The Calbuco volcano is one of the most active in Chile, but its eruption took officials in the area by surprise.

Alejandro Verges, an emergency director for the region, said Calbuco had not been under any special form of observation.

Source:http://ichef.bbci.co.uk/news/624/media/images/82521000/jpg/_82521685_026883262-1.jpg

Lidar Massachusetts

I have created several more Lidar maps but this time they are all based in Massachusetts. The Lidar data itself was not as high resolution as the Utah data since they are a few years older but they are fun to look at. What a difference a few years make as newer sensors and methods are used. My favorites are probably the Boston Harbor Islands and Provincetown maps. Enjoy!

If you would like to know more about LiDAR, click here

Sources: Mass GIS; NOAA

Lake Superior Ice Jam

I was listening to a report on NPR yesterday about ice jamming up a shipping route on Lake Superior. Every year when ice forms on the lake, icebreakers are needed to create shipping lanes for the passing container ships. The lanes around Whitefish Bay (in focus below with a 6-5-4 false color composite) have become completely covered due to drifting ice from earlier storms that compacted all the ice on the eastern part of Lake Superior. Some of the ice was reported to be eight feet thick as pieces piled on top of one another forming bigger chunks.  

The shipping lanes are being navigated through and cleared by a team of US and Canadian vessels. In this image you can faintly see the shipping lane which runs about 37 miles through Whitefish Bay alone.

Source: NPR, USGS, Google Earth Engine

Louisiana can't find their boot

Terra MODIS true color imagery 2/15/15

Google Earth Imagery 4/9/13

Landsat 8 true color imagery mult images stitched from throughout Feb

USGS 2011 National Land Cover Database data, showing how much wetland is left in Louisiana.

Louisiana doesn't look like the maps I memorized growing up anymore. Loss of wetlands has caused a dramatic change in the coastline. Imagery from Landsat 8, Terra, and especially the USGS dataset show the true story, but it is interesting to me that even Google Earth shades the imagery to show an image that we are used to seeing. Aerial imagery such as this can be a powerful tool to show what the situation is really like. 

There are a lot of reasons the wetlands are receding, chemicals that are dumped in the Mississippi River have caused problems in the area, as well as poor land management. Loss of wetlands allows for stronger hurricanes to hit the mainland, not to mention the loss of habitat to hundreds of animals

Here is an article that outlines the whole story - 
https://medium.com/matter/louisiana-loses-its-boot-b55b3bd52d1e

Lidar Utah

                                      

Wasatch Front Temperature

Summer of 2013 was one of the hottest on record for Utah. Normally the locals escape to the canyons for relief, since it is usually 20 degrees cooler than the valleys. But 20 degrees cooler than 107 is still very hot. Nighttime lows only got to about 75.  In an area that is not used to such extreme heat, it was difficult for many to cope. 

Images above show The Wasatch Front and Great Salt Lake on July 22, 2013. First image is a true color, second shows night land surface temperature represented by a color ramp and the third is daytime temperature. 

The bodies of water heat up and cool down slower than land, so during the day the water is cooler than it's surroundings and during the night it is warmer. 

You can also notice that the mountains are much cooler than the low valleys, still warm by Wasatch Front standards, but it beats sitting in triple digit heat all day. 

Grand Tetons

Grand Tetons, Jackson Lake, & Jackson WY
Landsat 8 6-5-4 False color composite
5-25-14

Lidar Salt Lake City

Introducing downtown Salt Lake City through the eyes of Lidar. This map

was made from public Lidar data from the AGRC. It is based off of a DSM 

(Digital Surface Model) that has been processed with a hillshade. It reminds 

me of a classic plat map or some of those city word art maps. Salt Lake's

unique geography really helps bring out this feeling. This will hopefully be

the first of many as I delve into other cities datasets and try to make similar ones. 

Please let me know if there are any cities in particular that you would like me to look 

at first. Also, if you are interested in a nice print version just send me a message or 

leave a comment below.

PS ~ This my first guest post on this blog. Thank you for setting it up Adam! 

Refinería Cardón Complex, Venezuela

Flare stack

Refinería Cardón Complex, Venezuela

These images show the usefulness of detecting wavelengths beyond the visible spectrum. The top image shows what would be considered a 'True Color image' or what one would see with the naked eye. The bottom image is reassigning the colors based on different wavelengths. Instead of Red Green and Blue showing the wavelengths that are Red Green and Blue, the values are showing different wavelengths that we can not detect with our own eyes.  This band combination is called a 6-5-4 false color composite. 

Red - Shortwave Infrared I (Band 6)

Green - Near Infrared (Band 5)

Blue - Red (Band 4)

This composite is especially useful for detecting vegetation, since vegetation reflects much more Near Infrared light than the others. You can see bright green in the areas that have vegetation. In this case it is also useful for detecting flare stacks in oil refineries. Those are the bright orange spots. I was snooping around in Venezuela using Landsat 8 imagery when I found this. It is one of the largest refineries in the world in terms of production. This image was taken on 2-18-15

Cool use of imagery - Heard about this on the radio this morning

Article Source - Written by Tanya Lewis

Seven giant craters have mysteriously appeared in northern Siberia, possibly due to methane gas released from melting permafrost. Check out these jaw-dropping photos of the strange geological structures. [Read full story about the Siberian craters]

This crater, in the Yamal Peninsula, was discovered in 2014 by helicopter pilots 19 miles (30 kilometers) from Bovanenkovo, a major gas field in the Yamalo-Nenets autonomous district. (Image credit: Marya Zulinova/The Siberian Times) 

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Four Arctic craters can be seen in this satellite image: B1, the famous Yamal hole located 19 miles (30 kilometers) from Bovanenkovo; B2, the recently discovered crater located 6.2 miles (10 km) south of Bovanenkovo; B3, a crater located 56 miles (90 km) from Antipayuta village; and B4, a crater located near Nosok village, north of the Krasnoyarsk region near Taymyr Peninsula. (Image credit:Vasily Bogoyavlensky)

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Satellite image of the site before the formation of the Yamal hole (B1). K1 and the red outline show the hillock formed before the emission of methane gas. Yellow outlines show potentially dangerous areas where gas could erupt. (Image credit: Marya Zulinova/The Siberian Times)

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Satellite images showing a mound of Earth before the gas emission that formed crater B2 (top). Lakes formed at a couple of the craters, and more than 20 smaller craters were found nearby (bottom). (Image credit: Marya Zulinova/The Siberian Times)

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The Yamal lake showing signs of gas emission. (Image credit: Marya Zulinova/The Siberian Times)

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Crater B3, located 56 miles (90 km) from Antipayuta village, Yamal district (top). Crater B4, located near Nosok village, north of the Krasnoyarsk region, near Taymyr Peninsula. (Image credit: local residents/The Siberian Times)

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The ring of soil around these craters suggests an underground explosion. (Image credit: Vasily Bogoyavlensky/The Siberian Times)

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The Russian Center of Arctic Exploration embarked on an expedition to Yamal crater in early November 2014. The researchers were the first in the world to climb down into the crater. (Image credit: Vladimir Pushkarev/The Siberian Times)

INSTAGRAM

60 followers! I'm the king of Instagram! Check it out @zoom.enhance

My new Google Earth Pro

East Canyon Reservoir  8/11/11

East Canyon Reservoir 10/7/2014

Here is a comparison over the years of a reservoir in the Wasatch Mountains using Google Earth Pro. Google just offered their high end Google Earth Pro license free for anyone. Which means you get to use their imagery for whatever purpose you want, which in this case, is for my high end blog that is viewed by millions every day. Thanks Google!

Utah, like most of the Western US has had a hard time with a water shortage. Our dismal snowpack this year shows us that things aren't going to get better any time soon. These two images, taken at roughly the same time of year 3 years apart show the change in water level, and it doesn't look good. I measured the surface area of the water by hand using Google Earth Pro and in 2011 the surface area measured 1.04 square miles, 2014? .58 square miles, almost half. I measured it by hand, not using any fancy classification, so it's not 100% accurate, but that's still not a good sign.

Salt Lake County Parcels

Salt Lake County, Utah
Parcels are symbolizing according to building age

Another quick project I did for fun. This shows younger buildings in dark and older buildings in light. Interesting to see how most of the county expanded from a central point, which is now downtown. Also you can see pockets of older communities that have expanded as well. Lots to learn from spatial relationships. 

SPACEX

The Many Band Combinations of Landsat 8

SOURCE: EXELIS BLOG

Landsat 8 is the most recent satellite in the Landsat program. The data quality (signal-to-noise ratio) and radiometric quantization (12-bits) of the Landsat 8 Operational Land Imager (OLI) and Thermal Infrared Sensor (TIRS) are higher than previous Landsat instruments (8-bit for TM and ETM+). Since it's launch on February 11, 2013, Landsat 8 has been providing some truly stunning images of the earth's surface. Beyond their beauty, these images are packed with information which can be manipulated to extract features and discern changes to the earth's surface over time.

When working with Landsat imagery, a logical first step is to load an image into an image analysis program and begin to visualize what is in the scene. The OLI sensor aboard Landsat 8 has nine bands for capturing the spectral response of the earth's surface at discrete wavelengths along the electromagnetic spectrum. Additionally, the TIRS sensor aboard Landsat 8 collects information at two discrete wavelengths within the thermal infrared portion of the electromagnetic spectrum. These wavelengths have been chosen carefully based on years of scientific research.

Standard digital cameras are designed to replicate what we see with the human eye, so they capture light only in the red, green and blue wavelengths and then apply red, green and blue filters (also known as channels) to these wavelengths, respectively, that when combined generate a natural looking RGB image. With a multispectral image from a sensor system such as Landsat 8, we have a lot more information to work with. Different wavelengths can often help us discern some features better than others or even help us "see through" features such as clouds or smoke. For example, the Near Infrared (NIR) wavelength is one of the most commonly used wavelengths on multispectral sensors because vegetation reflects so strongly in this portion of the electromagnetic spectrum that this information proves very useful when performing vegetation analyses. The Shortwave Infrared (SWIR) bands aboard Landsat 8 are very useful for discerning differences in bare earth and for telling what is wet and what is dry in a scene. There are many other examples of the advantages of the available bands in Landsat images, but what I would like to do here is simply show how loading different combinations of these bands into the red, green and blue channels makes different features stand out. I am not the first to do this, but I just thought I would add an additional resource to the world wide web for showing how these band combinations can be used to visualize Landsat 8 images.

4 , 3 , 2 - Natural Color Image, Fresno, California

This band combination is as close to "true color" as you can get with a Landsat OLI image. One unfortunate drawback with this band combination is that these bands tend to be susceptible to atmospheric interference, so they sometimes appear hazy.

5, 4, 3 - Traditional Color Infrared (CIR) Image, Colorado/Utah

Note how vegetation really pops in red, with healthier vegetation being more vibrant. It's also easier to tell different types of vegetation apart than it is with a natural color image. This is a very commonly used band combination in remote sensing when looking at vegetation, crops and wetlands.

7, 6, 4 - False Color useful for visualizing urban environments, Los Angeles, California

Because this band combination makes use of both of the SWIR bands aboard Landsat 8, the image is much more crisp than band combinations that make use of bands in shorter wavelengths, which are more susceptible to haze.

5, 6, 4 - False Color good for picking out land from water, Hudson Bay, Canada

In this false color image, land appears in shades of orange and green, ice stands out as a vibrant magenta color, and water appears in shades of blue.

7, 5, 3 - False color image with good atmospheric penetration, Washington/Oregon

This band combination is similar to the 5, 6, 4 band combination shown above, but vegetation shows up in more vibrant shades of green. This band combination was used for the global Landsat mosaic created by NASA.

6, 5, 2 - False color for agriculture, Fruita, Colorado

This band combination is useful for the monitoring of agricultural crops, which appear as a vibrant green. Bare earth appears as a magenta color and non-crop vegetation appears as more subdued shades of green.

7, 5, 2 - False color often used for visualizing forest fire burn scars, Rim Fire, California

This band combination is similar to the 6, 5, 2 band combination shown above, but by pushing further into the SWIR range of the electromagnetic spectrum, there is less susceptibility to smoke and haze generated by a burning fire.

6, 3, 2 - False color for distinguishing differences in bare earth, Canyonlands NP, Utah

This band combination is good for discerning variations in a landscape that does not contain an abundance of vegetation. It is good for geologic applications.

5, 7, 1 - False color for vegetation and water, Lake Victoria, Tanzania

This band combination makes use of the NIR, SWIR2, and Coastal Aerosol bands, respectively. The Coastal Aerosol band is unique to Landsat 8 and is used primarily to track fine particles like dust and smoke, and also to peer into shallow water. With this color combination, vegetation appears orange.

There are certainly several additional band combinations that would be useful for visualizing Landsat 8 scenes. In some situations, loading a grayscale image of a single band might also help to visualize specific features or phenomena. For example, in the grayscale image below, we are viewing the Thermal Infrared 1 band from the Landsat 8 TIRS sensor. This image, captured over Iceland, shows the Bardarbunga volcano in bright white in the top center of the image. Since we are using a thermal infrared band, this feature sticks out significantly from the ice sheet located just to the south of the lava flow.

With grayscale images, we also have the option of applying a color table to highlight features a little more clearly. In the image below we are viewing the same grayscale image of the Bardarbunga volcano, but now we have applied a color table that shows very cold extremes of the glacier in shades of deeper blue and very warm extremes of the lava flow in shades of deeper red.

There are many analysis techniques that can be applied to multispectral imagery to extract specific features of interest. These algorithms rely on the same principles of reflectivity and absorption at various wavelengths that allow us to see certain features when visualizing them with different band combinations. An important point to note is that if a particular band, or combination of bands, does a good job of helping you visualize a feature that is of interest to you, then it is highly likely that this band, or combination of bands, can be used to help you isolate that feature from your image. For more on this topic, please check out the section of our Documentation Center devoted to Spectral Indices.