It appears that a recent Java patch causes problems launching the IAS Viewer client and other Java-based software launched via Java Web Start. The update changed the location of the Java Web Start application so that the system opens the downloaded JNLP file as a text file, most likely with something called Dashcode. One of our system administrators found a solution on an Apple support discussion archive. You should only have to do this once to fix the problem:

1. Find any *.jnlp file in the Finder. These may be on your Desktop, or in a download folder, depending on how your web browser is configured.
2. Highlight the file by clicking on it, then select ‘Get Info’ from the File menu.
3. In the Open with: section, click on the popup menu and select ‘Other…’.
4. In the file chooser window that pops up, under Devices, pick the hard disk icon that corresponds to the name of your system hard disk (probably has the same name as your computer).
5. From there, select the System folder, then Library, then CoreServices, and scroll down to find the Java Web Start application, select it and click the ‘Add’ button. (Note, the location of Java Web Start application may differ on your system.)
6. Back in the Get Info window, click the button that says change all to apply this change to all of your JNLP files, then close the Get Info window.

When something tries to open a .jnlp file now, it should be properly handled by Java Web Start, launching the corresponding application.

Thanks to one of our twitter followers, @doug_ellison, for pointing out that many of you are having this problem!

Please note, we offer this for informative purposes, and you should make changes at your own discretion.

The solution for many NASA missions has been the development of the centralized Planetary Data System (PDS). The PDS is several things: a collection of websites, a search capability, an archive, a database, a learning tool, etc. The PDS Imaging Node is located at http://pds-imaging.jpl.nasa.gov/ and acts as “the curator of NASA’s primary digital image collections from past, present and future planetary missions.” These missions include Voyager, Galileo, Cassini, and many more. Now the Mars Reconnaissance Orbiter (MRO) has been added to the list, with the HiRISE team releasing our first several months of image data.

• MRO PDS page: http://pds-imaging.jpl.nasa.gov/Missions/MRO_mission.html
• MRO Product Search page: http://pds-imaging.jpl.nasa.gov/search/index.jsp
• HiRISE Volume: http://hirise-pds.lpl.arizona.edu/PDS/

What we have released is an archive of the HiRISE Experiment Data Records (EDRs) and Reduced Data Records (RDRs). EDRs are in the *.IMG file format and represent individual CCD channels (remember, there are 14 CCDs in the HiRISE camera and two channels per CCD, for a total of 28 channels). These EDRs are cleaned up, calibrated, stitched together, and mapped to Mars’ geometry, resulting in the RDR products. RDRs are in the *.JP2 and *.LBL formats. JPEG2000 is the technology that enables us to offer our gigantic images to the scientific community and the public in a timely and efficient manner. An observation’s image data are in the *.JP2 file and its meta data are in the detached *.LBL files. To view these products, JPEG2000 compatible software is required (see our site for a list of offerings).

While we have been trying to release up to five captioned images a week for the past few months, the PDS release represents several hundred images, most of them without captions. You can find them using the PDS search capabilities, and you can also find them on the new HiRISE site, unveiled today to coincide with this first PDS release. The redesigned site focuses on the images while providing, hopefully, a more user-friendly interface:

• HiRISE Site: http://hirise.lpl.arizona.edu/
• “About Our Redesign”: http://hirise.lpl.arizona.edu/profil.php
• Images released to the PDS: http://hirise.lpl.arizona.edu/pds_release.php

As word gets out about the new site and the PDS release, you may experience some site slowness. Please be patient, and thank you for your interest!

I changed it around a bit, hope you don’t mind, T!

1. You consider any image with less than a billion pixels a mere pittance… a negligible amount of data.
2. You realize that any part of Mars can be interesting, if viewed at sufficiently high resolution.
3. You start to see in black and white away from the “Center strip” of your eyes.
4. You have decided to buy a 500 Gigabyte drive just to store a few dozen of your favorite HiRISE Images.
5. You’re considering getting a new 40″ LCD mainly to look at HiRISE Images.
6. You know what JPEG 2000 is.
7. You start making up new Hi Names (HiStuff, HiSpace, etc, etc).
8. You continually refresh the web page starting Wednesday morning, waiting for the next release.
9. When using Google Earth, you wish you could zoom in further, just like HiRISE can.
10. You’re reading this!

The HiStitch pipeline combines the matching HiCal products for the same CCD into one more-or-less lined up CCD cube file. HiccdStitch combines these HiStitch cubes into RED, IR, and BG mosaics.

Both pipelines take some time, as overlapping pixels are accounted for and brought together. After these mosaics are created, additional steps create smaller jpeg files for easier viewing, and full-sized jpeg2000 files. We use these jpeg2000 files for validating our images.

There are later pipelines, but we first validate the HiccdStitch products: Did the previous pipelines work correctly? Did the uplink team command the camera correctly? Is there haze or clouds obscuring our view of the surface?

If everything looks good, and we have received the correct reconstructed SPICE ephemeris data, then the geometry pipelines are invoked. These pipelines project the images mathematically to a model of Mars and add geometry data to the images so that each pixel becomes a point on Mars with latitude and longitude coordinates.

The uplink team is constantly looking where to point the camera next. There is a program which is in beta testing now called HiWeb which allows scientists and other people to input suggestions. The Uplink team reviews the suggestions in the database, assigns a priority to each of these suggestions, and then finds when we can point the camera at the part. They also make sure a certain percentage of the upcoming pictures are assigned to look for a Phoenix landing spot, as this is a high priority item at the moment. They are still learning exactly how to best command the camera, and are constantly sharpening their skills.

The downlink team is making sure operations run smoothly at HiROC. They are verifying that the processing has taken place, make sure that the images have been calibrated correctly, that there are no image processing artifacts on the images we are about to release. If there is any artifacts created from processing the image, the source of the problem is identified and fixed, and then the image is reprocessed. While previously we have sent images to the public that had some small processing artifacts during the post-MOI and Transition imaging, we currently are waiting until the images have been completely validated. The downlink team is also taking a quick look at each image that comes down, and making sure there isn’t something unexpected, for example, haze at Mars, lots of saturated pixels, etc. If any such problems are found, they notify the uplink team, to ensure that we don’t have continuing problems. These problems are very rare, but on occasion happen, due to the changing nature of Mars.

During and after the validation process, the images are reviewed by several of the science team members of HiRISE. Things of special nature are noted, and these images receive captions. The others are slated for a more general release. Due to the large size of the HiRISE images, it is almost impossible to search every square inch of the pictures by any one or even a small group of people. I’m sure many of you have noticed this with just the images which have been released, there are many more which are still being validated which have yet to be released.

The Systems team is responsible for making sure that the HiROC computers are all working in top shape. They are quick to find problems when they arise and fix them so that it does not affect the flow of data here. They are preparing servers for two upcoming services that HiROC will provide, HiWeb, which was mentioned previously, and a JPIP server, which will allow for the effective distribution of JPEG 2000 images.

The software team is writing software that will make people’s lives easier. Some are working with the HiPlan suite of tools, which is used to plan upcoming images, to make it even easier to use for the uplink team. Some are working on HiVali, the validation software, which is used to make it easier to verify that an image is ready to release to the public, quickly finding problems with the image. Some are working on HiView, a program which will allow distribution of images over the JPIP protocol to the general public. Still others are working on getting HiWeb ready for public release.

Let me also talk a bit about a few upcoming products mentioned in this entry. HiView will allow you to download only the parts of a HiRISE image that you find most interesting. It will work great, even for those who have slow internet connections. I personally have tested this with a connection rate of 1kBytes/sec, and it works reasonably well even at that slow speed. It will allow the user to save the parts of the image they find the most interesting to their hard drive for future study (HiView will require a constant internet connection to download the image)

Another upcoming product is HiWeb. HiWeb will allow any user (Yes, that’s you!) to suggest future targets to image with the HiRISE camera. Preference is given to targets of scientific interest. The suggestions are given a priority, and placed in a database to be targeted depending on the orbit of MRO and the allocated bandwidth.

So, that’s what’s happening at HiROC these days. In short, we are all very busy, but very much enjoying our work. I personally can’t remember a time that I’ve had as much fun working as these last few months have been. And surely the best is yet to come!

Actually, today we got 31 TRA images out the door, just about completing that set. In addition, the previous 32 grayscale images have been reprocessed with our improved geometry—no more jagged edges on the reprojected “Red Mosaics”.

Furthermore, the full-res images are now available as lossless JPEG-2000 (JP2) files. At HiROC we are using the ExpressView application from a company called LizardTech… a subsidiary of some Japanese company (that has no affiliation to us FWIW).

ExpressView is available for Mac and Windows. Their download page describes it only as a browser plug-in, but the installer contains an application as well.

ExpressView provides progressive rendering (though you still have to have the entire file first—we are considering moving to a streaming model using the JPIP protocol but there are even fewer clients available). It should also reduce the amount of memory (RAM) needed to view our largest images.

There are a few options available to Linux users, but nothing we have tried is as fast or as feature-rich. In any case, let us know what works or doesn’t work for you.

All of these images are available at the usual location.

A system for streamlining the process of editing captions, highlighting cut-out areas and pushing out web pages is in the works. We will get caught up.

In the meantime, look for the first set of PSP releases by this time next week.

P.S. Happy Thanksgiving.

We are waiting for reconstructed SPICE ephemeris data, which comes out every Wednesday – starting next week – before sending these data through our geometry pipelines, and ultimately releasing them to the scientific community and public. Last time, we forced images through our geometry pipelines using predicted SPICE kernels; we do not want to double our workload by continuing that practice. The SPICE kernels released next Wednesday will cover some of the images captured this week.

Once the images have been visually and statistically validated and the matching SPICE kernels have arrived, one of the downlink folks will send the images through the geometry pipelines. We also need to get a select group of captions written and automatic caption information generated for the rest.

We are producing JPEG2000 products now in addition to smaller jpeg browse images, to be ready for our viewing client when it is ready for public release. However, there are many different JPEG2000 viewers and plugins already out there to start practicing with. One example is ExpressView from LizardTech.

Once we are on a roll, the data release will be steady and no one will be able to keep up with the wealth of Mars data coming in. Until the first public release of PSP images, we will try to provide here on HiBlog more details about the many tasks that must still be completed.

This was the third test in a series of 4 tests. The purpose of this test was to begin ramping up the volume of products we released, to test our first JPEG2000 product, and to test the ability of the node software to distribute files that are larger than 2 Gigabytes. We are still learning how to make proper JPEG2000 files, but we did learn that the PDS node server software was successfully able to serve these large files. The ability of different clients to download such large files was a little more spotty, but this was not completely unexpected since there are many clients that are incapable of downloading files this large.

This test gave us a pretty good idea about how downloading such products might work by conventional means. However, our plans are to serve our JPEG2000 products using the jpip protocol which will allow clients that understand this protocol to pan and zoom around portions of our images without downloading the entire file. In most cases, you probably do not want to even try to download such large images in the first place.

1. The image is taken by the HiRISE camera, and is stored in up to 28 channels, two for each of the 14 CCD arrays of the camera. Each channel covers about half of the image. Of the 14 CCDs, 10 are red CCDs, two are blue-green, and two are near-infrared. The color CCDs are aligned with the center red CCDs.
2. The image is placed inside a buffer on MRO, awaiting transmission to Earth, along with science data from the other instruments on MRO.
3. The image is received in packets by the Deep Space Network (DSN).
4. After 4 hours of collecting data at the DSN, the Jet Propulsion Laboratory (JPL) puts the packets together for what is known as a “quick look”. The entire image generally has not yet been received by this point in time, but it is enough of the image that it can be processed to take a quick look at it. Subsequently, JPL puts together all of the data it has received every 4 hours and makes it available to the computers at HiROC.
5. After the files have been put together by JPL, then one of the computers at HiROC looks and sees that there is data on the JPL server and copies the data to our system at HiROC. This is the start of what is known as the pipeline, the system of programs at HiROC which process the images. This usually happens either via a direct connection to JPL (slower), or through the Internet 2(Faster, but sometimes can be bogged down).
6. The images are put together into a viewable format, using the minimum processing possible, and create what’s known as an EDR, or Experimental Data Record. This is done without calibration, stitching together the channels, or any other processing, aside from putting the image together. For an image which uses all 14 CCDs, there will be 28 EDRs. These generally speaking are of mainly scientific interest, but they will be released to the general public via the Planetary Database System (PDS). They will be in the standard PDS format.
7. After the EDRs have been created, they are converted to another format for ISIS. ISIS, the Integrated Software for Imagers and Spectrometers is a suite of tools used for processing images for most interplanetary missions, that was developed by the United States Geological Society (USGS). Most of the tools that we use at HiROC for processing our images are written for ISIS files.
8. After the ISIS files have been created, they are calibrated via a program called HiCal. This reduces the inherent noise of the camera to be more consistent with what is being photographed. All digital cameras create some level of noise, and while HiRISE is an extremely good instrument, it still generates a low level of noise.
9. After the individual channels are calibrated, then they proceed to a program called HiStitch, which puts the two channels of the same CCD together. As they are a part of the same CCD, this requires little processing.
10. Next, after each CCD been stitched together, the full CCD images run through a program called HiccdStitch. This program puts the different ccds together, making a mosaic for each color band. This requires some processing, as the ccds slightly overlap, and it can sometimes be difficult to match the different arrays exactly.
11. If the image has not been completely received, then at this point, the pipeline stops, until JPL has received the entire image, or if there are a few confirmed gaps in the image which we haven’t been able to recover. Transmission over the vast distance between Earth and Mars is not easy, and even the best systems have some small error.
12. After the image has been completely stitched together, then the image is geometrically projected. To understand this, realize that the images that HiRISE takes are flat, while Mars is actually round. Geometrical Projection alters the image so that the image points in compass directions, while correcting any distortions that are created by the ellipsoidal shape of Mars. With the geometrical projection images and the right software tools, such as qview for ISIS, the exact distance can be found between two point on the image. In order for this to happen, we must wait for information to be gathered on the exact position of the spacecraft. This is done by the nagivational team, based off of the downlink frequency. This takes two weeks after the picture has been taken, so Geometric Projection might take a while. This is the longest wait point of the operation. An image can be released from predicted information, however, most images will wait for the correct SPICE kernels to be calculated, in order to get the best information. If an image is geometrically projected from predicted information, it will be calculated with the correct info after it has been received.
13. The images are then validated by a team of students known as the HiRISE Validators. They check to make sure that everything in the pipeline worked perfectly, see if there are any gaps in the images, and other similar tasks. If they notice a problem, they contact the HiRISE Operators, who will take steps to resolve the problems, which may include passing part or all of the image through the pipeline again, or tweaking the software to make it work perfectly.
14. The image is converted to a format that the general public can use. Currently that format is JPG, or TIFF, but eventually we will use JPEG 2000.
15. After all of this, the science team members of HiRISE will look at an image to see if there is anything noteworthy. If there is, it is given a caption, and perhaps a press release. If not, it will be posted on the HiRISE website. They are also posted on the MRO website, and occasionally on others.

This process may take as long as a week or two to complete, depending on the load of MRO, scheduling concerns, load at HiROC, etc. The first image took about 9 hours to be completely processed after it was taken by HiRISE. The Victoria Crater picture, taken during a much busier time on MRO, took about 36 hours to make its way to our hands. This was in part due to the larger size of the image, as well as the cache of images already awaiting transmission on MRO to earth. The captions for the images taken during Transition imaging took anywhere from a few hours to a few weeks to write, and this will likely continue to hold. We at HiROC want to release the images we take as fast as possible to the public, and we are doing everything we can to realize this goal. Several shortcuts were taken during the Transistion imaging phase that allowed for images to be released quicker. For Primary Science Phase, this will take a bit longer because these shortcuts will not be taken, but we expect that we will release most images within two weeks after them being taken, shortly after we have finished receiving, processing, and captioning the image.

There are some variations to this process, for example, the Victoria Crater picture was released in a press conference jointly with the Mars Exploration Rovers (MER) team. Also, color images require extensive calibration and take a lot more time. However, this is the general idea. Currently the entire system, except for writing the captions and adding the images to our website, is essentially completely automatic for receiving and processing HiRISE images, due to years of preparation by the HiTECH and HiOPS teams.