July 15, 2007 at 4:07 am (Tutorial)
Sudah lama ingin posting tulisan ini, tapi baru sekarang sempetnya. Menanggapi banyaknya siswa dan temen lama yg bertanya bagaiman caranya memperbaiki Harddisk yang rusak. Secara awam mungkin sulit untuk memperbaikinya, tetapi secara teknis harddisk yang rusak bisa diperbaiki, tergantung level kerusakannya.
Cerita dikit tentang Harddisk
Saya membagi harddisk menjadi 4 level, ini bedsarkan riset dan pengalaman saya pribadi selama menangani kerusakan harddisk.
June 9, 2007 at 10:50 am (Tutorial)
Redemption for LGA775?
IF YOU’VE BEEN paying attention over the last few months, you’ve no doubt noticed that AMD’s latest Athlon 64s trounce Intel’s newest Pentium 4s almost across the board. That’s a real shame considering that Intel’s 900-series chipsets bring so much to the table, including PCI Express, advanced Serial ATA and RAID features, and high-definition audio. There could be hope for Intel fanboys, though. Since the Pentium 4 500 line stretches from 2.8 to 3.6GHz, lower speed grades may have considerable overclocking headroom just waiting to be exploited.
How much headroom? I got an extra 770MHz out of my Pentium 4 520 2.8GHz, which is quite comfortable running at 3.57GHz with stock air cooling—not bad for a chip that costs less than $160. Could a little help from the overclocking fairy make the Pentium 4 520 2.8GHz a formidable contender against the Athlon 64? Read on to find out.
The overclock
The Pentium 4 520 2.8GHz processor we’ll be overclocking today is an off-the-shelf retail unit that wasn’t cherry-picked or pretested for overclocking potential. I also shied away from using more extreme cooling solutions in favor of Intel’s stock LGA775 cooler. Water cooling, volt-modding, or other more extreme measures may be able to take the processor further, but they’re quite a bit more involved and expensive than our stock setup.
The Pentium 4 520 2.8GHz
Since Intel has gone to great lengths to hinder overclocking with its 900-series chipsets, choosing an appropriate motherboard is essential. In the end, I settled on Abit’s AG8 for several reasons. First, the AG8 offers more tweaking and overclocking options than any other LGA775 motherboard I’ve encountered. The board also supports DDR400 memory, and at only $125, keeps with our budget theme.It also happens that my Pentium 4 520 2.8GHz is perfectly stable on the AG8 with a 255MHz front-side bus, yielding a processor speed of 3.57GHz. Reaching 3.57GHz required a couple of tweaks, though. First, I had to bump the processor voltage up from 1.3375 to 1.4125V. That’s not a big boost, but the system wasn’t stable without it. I also had to swap in memory capable of running on a 255MHz front-side bus. A pair of PC4400 sticks rated to 550MHz DDR did the trick, but with a little extra baggage in the form of more relaxed timings. The PC4400 memory has 2.5-4-4-8 timings, while the PC3200 memory I use at stock speeds runs with tighter 2-2-2-5 timings.
Unfortunately, even fancy high-end memory has problems running with 2-2-2-5 timings on a 255MHz front-side bus, so we’ll have to make do with 2.5-4-4-8 timings while running at 3.57GHz.
3.57GHz with stock air cooling and only 1.41V, not bad at all
Of course, no discussion of overclocking would be complete without the usual disclaimer. Overclocking success can depend as much on the unique characteristics of individual system components as it can on the proper alignment of planets and pure, unadulterated luck. Just because I was able to get my Pentium 4 520 2.8GHz stable at 3.57GHz doesn’t mean that every chip will overclock as high, or that other chips won’t go higher. As always, your mileage may vary.
>>> techreport.com
June 9, 2007 at 10:44 am (News)
If you are looking for a satellite technology that is stable and predictable for your various applications, Galileo has a proven track record with many companies across North America. Proprietary data stabilization technology delivers both speed and reliability. It has near perfect error rates and incredible low overhead to reduce satellite latency to a bare minimum which means Galileo is an excellent platform for numerous VPN, VOIP or other in-house applications that may crash over other satellite networks. Galileo is the best a satellite network can provide for both application performance requirements and speed.
North American Coverage Map
No need for complicated “link budgeting”. The Galileo Satellite footprint covers most all of North America for use on a standard 1.2 meter dish. This KU band satellite is situated at a longitude of 101 degrees. Click for a larger picture.
IRAQ Coverage Now Available – more
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Many companies have unique applications they run over their network that may crash or become slow over other satellite networks. The Galileo Network has been designed to compensate for these issues and eliminate the majority of problems. TEST IT NOW… If your software will easily install on a standard PC running Windows XP, call us and we’ll install it on our live demonstration system to confirm it works.
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Galileo’s highly optimized network and proprietary encoding software is friendly toward many company VPNs including Citrix. Or Ground Control can create a VPN solution for you. We recommend you demonstrate our system if you are new to satellite, or are having problems with any other satellite provider.
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Galileo is tuned for maximum IP performance over a satellite link. A low BER (Bit Error Rate) of 10 –10 (nearly error free) allows for the fastest performance over a satellite link for TCP/IP traffic.
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The most important aspect of any service provider is the level of support they can provide. Ground Control was founded and continues to develop around one simple truth, unsurpassed customer service and support 24-7, and quick responce field support available anywhere in the United States.
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The Galileo Satellite Dish |
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Galileo Gateway The Galileo Gateway (1RU) is the only indoor equipment needed for the system. It contains both the satellite modems (send-and-receive) as well as a web based gateway that can connect to your network router. |
A Service Level Agreement – SLA (Now included at not additional cost)
For those that purchase the Galileo Service Level Agreement, Ground Control will guarantee your speeds and your service connection from fault or Ground Control will refund a portion of your monthly expenses. - SLAs are now available at no additional cost with all fixed systems more
Public IP
A publicly routable static IP address is available with every Galileo account. Additional IP addresses are available for an additional cost.
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Ground Control will create the kind of network topology you require for any level of security you demand. more
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Galileo is now available with the Magellan MSS mobile .95 meter satellite system. Create a mobile office. more
De-icing
For an additional cost, your satellite dish may be equipped with a de-icer so that snow will not build up on the dish, degrading your satellite connection.
>>>www.groundcontrol.com
June 9, 2007 at 10:24 am (Tutorial)
The Somewhat Complete AMD 64 Overclocking Guide.
XT-ChAce (And WicKed) have another A64 guide Here I Couldnt find it the other day when I wrote this. This guide offers a few more definitions, and a more detailed “How To” A Little bit more tedious approach to overclocking, but my results with this method have been very good so far.
Since we are constantly inundated with requests on how to Overclock ones A64 System, I Figured I’d take a stab at a guide.
I’ve been Overclocking Computers for about 15 years, so when I built an A64 rig about 8 Months ago, I figured it would be the same as always…. (I’m now on my 3rd A64 Rig…..)
I was wrong….
Critical Overclocking Programs you’ll need:
CPU-Z: General System Monitor and report.
ClockGen: Make sure your get the version for your Chipset. This program allows you to Overclock from within windows. Not always as reliable as physically changing BIOS settings, but gives you an easy way to play with your settings without dozens of reboots.
Memtest86: You’ll need to run this from a Floppy or Bootable CD. This basic program is still considered the best for testing your RAM
SuperPi: Intensive mathematical program that stresses CPU/Memory pretty extensively. I like this program because it gives you a good indication of your overclock in under a minute’s time.
== Critical Components for a Quality Overclock ==
POWER SUPPLY Power Supplies are missed so often when it comes to figure out why your system isnt overclockig the way it should. DONT SKIMP HERE! Get yourself a quality Power Supply and you’ll never regret it. The Power Supply that comes with most cases is garbage. If budget is tight, Go with an ANTEC or ENERMAX case. These usually come with a pretty decent supply. FOr detailed Power Supply Information, see DavidHammock’s Power Supply Guide
RAM Ram has come a long way since A64’s have been Introduced. Balancing Speed and Timings is Critical for best overall performance. FOr 1 gb kits, TCCD and UTT/BH-5 are excellent. FOr 2gb Kits, look for Infineon or Micron Chips. My personal favorite right now are the G.Skill HX series. Great speeds with excellent timings.
There are several more factors that go into a quality and Stable A64 Overclock, that there are with Older XP and Intel based systems. A few of the factors we need to take into Consideration are
CPU Multiplier
CPU Voltage
HTT Frequency
HTT Multiplier
Memory Divider (There is ALWAYS a memory Divider with a A64 system)
Memory Voltage
Ram Timings
Chipset Voltage
AGP/PCI Lock
COOL N’ QUIET
Finding the right combination of these settings is the only way to get the most out of your A64
CPU Multiplier All A64s are at least Half Locked. This means that you can set the CPU Multiplier Lower than stock, but not Higher. This is a Good thing. Very rarely with A64’s would you ever need to raise the CPU Multiplier over the Factory setting. The exception to this are the FX chips, they are fully unlocked.
CPU VoltageMost A64s have a default voltage of 1.4v to 1.6V. A64s are extremely efficient and usually can only take about 1.7v before they just start producing excess heat. I’ve run my Mobile up to 1.9v but found it did NOT help my overclocks and simply caused the CPU to produce enormous amounts of heat. These are NOT XP-M chips! While I doubt that running voltages between 1.75 and 1.9 will cause any permanent damage, it certainly has not shown to be beneficial in any tests I’ve seen so far.
HTT FrequencyA64s don’t use a traditional Front system Bus. Instead they use a HyperTransport. I can only assume its abbreviated “HTT” to differentiate between Intel’s “HT” and Hyper-Threading Technology. They are VERY different.
The HyperTransport is what controls the base frequency for communications and CPU speed in our A64 System. The CPU Speed is controlled by the HTT Multiplied by the CPU Multiplier, The HyperTransport or Memory controller is controlled by the HTT Multiplied by the HTT Multiplier, and Memory speed is controlled by the HTT Frequency, Multiplied by the CPU Multiplier and then DIVIDED by the Memory Divider. That’s a bit confusing for most folks. And it took me a while to grasp the concept as well.
HTT MultiplierMost AMD Motherboards are designed to handle an 800-1000 MHz Hyper Transport bus. Factory Default on 754 CPUs is 800 MHz (A 4X Multiplier) and 1Ghz (5x) on 939 CPU’s this is a Critical part of Overclocking an A64 to the Max. Pushing the HyperTransport past 1Ghz can cause all kinds of system instability that is commonly misconceived as “I maxed out my CPU” or “My Ram is holding me back”
Memory DividerThis is one of the most Confusing aspects of A64 Overclocking. There is ALWAYS a memory divider. Setting the Memory to 1:1 means that the HTT bus is multiplied by the CPU Multiplier and then Divided by the CPU Multiplier to set the Memory speed. This means that it is OK to run your Memory at its peak efficiency and still go higher with your HTT bus if your CPU can take it. Take note that I said its “OK” not advisable. There are still sufficient tests out there showing that running a 1:1 ratio will garner you the best overall performance. I plan on adding a few test results in the next week or so showing the difference in performance using a higher memory divider than CPU Multiplier.
Oscar Wu’s Memory Divier Chart
Since A64’s use an On chip memory controller, the Ratio must be calculated a bit differently than old. 5:6 is NOT always 5:6. See that chart at the end of this post for a prety darn close representation of what each divieder is doing. Thanks to Oskar from DFI for the chart.
Memory Voltage Most motherboards offer a degree of memory voltage options. The memory of choice lately has been Samsung TCCD Based modules with Brainpower PCB’s. These Modules run at 2.6v stock voltage, and can usually do no better with voltage up to about 2.8-2.9 volts. There have been a few reports of better settings with voltages over 3v, but these seem to be pretty rare situations.
Most other memory can benefit from having additional voltage run through it. The king of this is the elusive Winbond BH-5 based memory modules. If you’re lucky enough to have some of these, you may want to invest in an OCZ Memory Voltage Booster if your motherboard is compatible as these can run some very impressive timings with a lot of voltage…. Speaking of Timings…
Memory TimingsThere are 5 Numbers in our Timings that we need to worry about a lot. Personally, I would like to learn more about the other numbers, but as of this writing, I’m pretty much in the dark there.
What we do need to worry about are CAS Latency, RAS to CAS Delay, RAS Precharge, and Cycle Time(Tras), and CPC (command Per Clock) Ideally, we want these timings to be 2-2-2-5 1T. Most TCCD based module does this at 200 MHz (DDR400) and can usually go up to 215-220 with a Bump in Voltage to 2.7, and then we need to loosen them to go higher. 2.5-3-3-7 is still considered reasonable memory timings for an A64 system, and some people even go out to 3-4-4-8, but I would personally advise against using timings that high with an A64 System. We ALWAYS want to use CPC (1T) this means the Command per Clock interface is enabled. 2T performs extremely poorly on A64 systems. But since our memory controller is on the CPU, the Double Sided memory problem that plagues XP Motherboards is not evident. Give AMD a WOOT for that one…..
Chipset VoltageUsually just a small bump in Chipset Voltage will stabilize a flakey HTT bus. 1.6 is Stock on most motherboards, but 1.7 to 1.8 is acceptable as long as you have decent cooling on your Northbridge chip. Many A64 Motherboards use Passive heatsinks on these chips so before you install your dandy new A64 system, take off your NB Cooler and replace the Factory thermal past with some AS-5. This is usually enough to keep the MB Cool enough to run the extra voltage. Placing Ram Sinks on your Southbridge and any other heat producing chip is never a bad idea either.
AGP/PCI Lock
The AGP and PCI Bus’ are tied together on all motherboards that I know of. They are also derived from the FSB (Or HTT in the case of AMD) frequency by a divider. NVidia NForce chipsets have whats called a PCI/AGP Lock. This keeps your PCI and AGP Bus at a constant speed no matter what your HTT bus is. This is CRITICAL. If y our PCI bus is too fast, you WILL corrupt hard drive data. If your AGP Bus is too fast, you WILL have Video problems. Via Chipsts have been known to have Faulty PCI locks. This appears to be corrected in the KT800 Pro Chipset, but KT800 and below SHOW a PCI Lock in most bios’s but it doesnt do much… This is a Primary reason why overclockers stay away from these boards.
On your Nforce or Via KT800Pro board you want this setting at 33Mhz if its listed as a PCI lock, or 66-67Mhz if its listed as a AGP Lock. Pushing this offers absolutely no benefit as the bandwidth provided by these frequencies is more than todays Hard Drives or AGP Video cards can use. COOL N’ QUIETDisable this. This is a feature that will automatically UNDERCLOCK your system if it feels it doesnt need to run so fast…. WHo are “They” to tell us how fast out CPU should run?
Now…. What do we do with all this Information??? Start Overclocking of course…..
First Thing First… Let’s see how fast our Processor can go.
Set your Memory Divider at its lowest setting. (Usually 100 or 133) This will give us a LOT of headroom to push out CPU.
Next, Drop your HTT Multiplier to 3x and your CPU Multiplier 1 Notch (If you have a 2 GHz CPU, drop your Multiplier down to 9x)
with these settings most AMD systems will boot and run at a 230HTT so go there first. Once you get into Windows, Run a 1Million run of SuperPi, and then a Prim95 Max heat test for about 10 Minutes. If it passes both of those, its time to go further. Go 5 MHz at a Time and Repeat. During this we’ll want to raise the VCore of our Processor to maintain stability. Once SuperPi and/or Prime95 fail, raise your VCore .05 Volts and Try again. SEE CPU Voltages Ademdum at the end of this guide for processor specific Voltage recomendations.
This is a Slow Time Consuming process, so have a few Mountain Dews and some chocolate bars handy.
Once your push your HTT bus back over 800 MHz (267HTT Bus) raise your Chipset Voltage up to 1.7
with any luck, you’ll hit 260-280HTT Depending on your CPU.
Write this info down and then we move on to testing out Memory. CPU TEMPS ADDDENDUM As stated above, A64s are VERY efficient, there have been reports of outrageous overclocks using the stock AMD Heatsink. But I would still recommend a high quality Swiftech or Thermalright Unit. (Dee DavidHammocks HSF Guide for specifics)
Anyway, Standard Desktop chips should be kept under 55c in ALL cases. It should NOT be hard to keep then under 45-48c with good quality cooling. Running higher than that is a good indication that you have misapplied your HSF and/or AS-5 Remount. Mobile chips are rated a bit higher, but there is still no reason to ever see temps higher than 55c. The lack of an IHS provides better contact with the Heatsink and it’s very possible to keep temps at 45 and lower with quality cooling. Even with high overclocks.
Drop your HTT bus back down to 200, and reset your Memory Divider to 1:1 (Usually “AUTO”) Leave your CPU Multiplier at 9x (For a 10 Stock Multi) and let start out at 215 at Stock Timings, Bump VDimm up to 2.7v(Or +.1Volt)
The 2 tests you want to do here are SuperPi 1 Million and Memtest86 You’ll need a Floppy disc or Bootable CD to run Memtest86 (Or if you have a DFI UT, there is a Modded BIOS available with Memtest built in)
Run 5 Passes of Memtest86, then boot into Windows and Run SuperPi. You won’t be fast, but SuperPi 1Million runs a LOT of numbers through your Memory. If all goes well, go up 5 MHz at a time until one starts to error. That’s where we need to start loosening the timings. Go up .5 on Cast Latency, 1 on RAS to CAS Delay, 1 on RAS Precharge, and 2 on Cycle Time (Tras) and Repeat these tests. Depending on your memory, you may want to loosen them more, but I would suggest keeping them under 3-4-4-11 if at all possible. If you’re using Memory Other than TCCD based, don’t be afraid to bump your Memory voltage more. Most modules will take 2.9-3.0 Volts just fine and BH-5 has been known to go as high as 3.3 to 3.5v!
Once you’ve found your Memory’s max speed, this is where we need to do some math. Most likely there’s a sizeable gap between what your CPU can do and what your Memory can do. That’s OK…. That’s why we went down a Notch or 2 on our CPU Multiplier testing.
Lets say your CPU went to 260 Stable with a 1x drop in your Multi, Not bad…. a 340Mhz O/C on a stock 2Ghz chip… but your memory only went to 230 before you had to go to slow in your Timings. That’s OK…. Drop the HTT down to 230 and bring your Multiplier back to stock speed (10 xs in our example) you should have a Rock Solid 300Mhz overclock on your hands.
If the Gap between your Memory and CPU is so high, you can’t get to your Max CPU Speed with your Stock Multiplier, we may need to run a higher Divider on our Memory. If we’re talking 30+ MHz base difference…. You should probably drop your Memory Divider down to 166 and use your Max CPU Speed we figured out. Less than 30 MHz and you’ll probably get better performance running 1:1 at your Memory speed. I say this because we’ll be losing memory speed at our best settings at that point. Only use a Higher Divider IF your CPU speed will bring your Memory speed to within 2-5 MHz of your MAX Memory Speed. 240HTT X10 = 2400Mhz, Divided By 11 (166) brings out Memory down to 218Mhz If out MAX speed as 236, we’re Giving away Memory bandwidth for no reason. However, if your Max CPU bus is 260, then we get this 260×10 = 2600 /11 = 236. See how that works? Now out Memory is maxed AND out CPU is maxed….
AMD64 Processor Voltage Guidelines
This guide is designed to give everyone a good idea of the voltages you can run on your A64 CPU’s.
Unfortunately, this chart is based on Observation and personal experience. There is ALWAYS a risk when playing with CPU Voltages. If you Blow your CPU up in the “SAFE” range, IT’S YOUR FAULT. If you cannot accept the Risks of Overclocking, then DON’T DO IT.
I’d like to thank Dil-Tech for This Thread as it is the basis for this chart.
Voltage Guide
I have Personally overclocked the following processors: Newcastle Clawhammer Clawhammer Mobile Winchester Venice San Diego
I have taken ALL of them into the “Insanity” level on AIR COOLING. I have yet to Blow up a CPU. But I am the definition of a risk taker. I can afford a new CPU if and When I blow one up and would never blame anyone but myself when catastrophic results present themselves.
Don’t Miss This Sticky from XT-Chance as it contains a lot of detailed information on the cores listed below.
BEFORE USING THE INFO IN THIS CHART Ask yourself these Questions:
1: Can I afford a New Processor? If the answer is YES, that’s great. If its NO, then I would personally reconsider messing with my CPU Voltages.
2: How Stable is my Power Supply? Do you even Know???? Even a quality supply can have rail issues. I have a Vantec Stealth 520 that Droops 12v and had an OCZ420 go bad on me. Read Jasons reviews on Power supplies. He has one of the best Test rigs out there and can truly get a good idea of how they respond to loads. Also take note of Davids Power Supply Guide and last but not least TEST YOUR SUPPLY If you disagree with the voltages or temps stated, please let me know and why. I’ve been doing this a long time and I’m very confident in my recommendations but I am also defiantly open to learning more.
http://wiki.extremeoverclocking.com/images/6/6d/VoltageChart.JPG
http://wiki.extremeoverclocking.com/images/a/a6/OscarChart.JPG
This guide was Written Completely on the Fly. Any Similarities to other AMD64 Overclocking guides is purely coincidental, I hope there’s enough new and/or important information here for newbie’s and expert alike…..
>>>wiki.extremeoverclocking.com
June 9, 2007 at 7:16 am (News)
PASADENA, Calif. – NASA space technology is helping doctors diagnose and monitor treatments for hardening of the arteries in its early stages, before it causes heart attacks and strokes.
Hospitals and doctors around the country are using ArterioVision software initially developed at NASA’s Jet Propulsion Laboratory (JPL), Pasadena, Calif., along with a standardized, painless, non-invasive ultrasound examination of the carotid artery, which carries blood from the heart to the brain.
A standard carotid ultrasound measures plaque and blood flow within the artery. When an ultrasound is used with the software, the test measures the thickness of the inner two layers of the carotid artery – the intima and media. Medical Technologies International, Inc. (MTI) of Palm Desert, Calif., patented the ArterioVision software.
Arterial thickening provides the earliest evidence of atherosclerosis, or hardening of the arteries, the beginning stage of a disease process that leads to heart disease and stroke. Doctors can use this carotid intima media thickness (CIMT) measurement to calculate the age of the patient’s arteries, which does not always match the patient’s calendar age.
“You may look and feel one way on the outside, but your arteries actually could be much older than one realizes,” said Dr. Howard N. Hodis of the Keck School of Medicine at the University of Southern California, Los Angeles. “Once patients see how thick their arteries are, there is much more incentive for them to change their lifestyle with dietary modification and exercise,” he said. “Physicians also can use the test to monitor and change current medications.”
The U.S. Food and Drug Administration has approved the new diagnostic tool, called the ArterioVision CIMT procedure. Robert Selzer, MTI chief engineer, worked in JPL’s Image Processing Laboratory for 15 years, where the technology was developed that ultimately led to the software used in ArterioVision.
“This is such a precise method of examining the carotid artery. It can distinguish between 256 shades of gray at a subpixel level,” Selzer said. “You need that kind of detail to help catch heart disease as early as you can, often before there are any outward symptoms.”
During the test, a patient lies on an examination table while a technician applies gel to the neck to image the carotid arteries, located on both sides of the neck near the skin’s surface. The technician uses an ultrasound machine while following a patented protocol to capture specific images of the carotid artery wall. Using the ArterioVision software, the physician generates a CIMT measurement and a report that identifies the patient’s risk profile when compared to people of the same gender and age.
JPL’s Image Processing Laboratory was created in 1966 to receive and make sense of spacecraft imagery. In the lab, the NASA-invented Video Imaging Communication and Retrieval software has been used to process pictures from numerous space missions, including the Voyagers and Mars Reconnaissance Orbiter. Periodic upgrades of the imaging software have enabled greater accuracy and improved knowledge of our solar system, and have laid the groundwork for understanding images of all kinds.
The ArterioVision test was developed with JPL’s Innovative Partnerships Program, designed to bring benefits of the space program to the public. “It is exciting to see this NASA-funded technology grow in sophistication over the years and help in the battle against one of the nation’s leading health issues,” said Ken Wolfenbarger, Innovative Partnerships Program manager at JPL. The American Heart Association says heart disease is the leading cause of death in the United States, while strokes are third, behind all forms of cancer.
Gary F. Thompson, chairman and chief executive officer of MTI, says the test is near and dear to his heart – literally and figuratively. “I was the first male in my family to reach 50, so I decided to celebrate by running the Los Angeles marathon, but I had a heart attack halfway through it and couldn’t finish,” Thompson said. “None of the non-invasive tests that I had prior to the marathon detected my silent heart disease, and I knew there had to be something better out there.”
The California Institute of Technology, Pasadena, which manages JPL for NASA, licensed the ArterioVision device to MTI. For more information about ArterioVision, visit:
For more information about NASA’s Innovative Partnership Programs, visit:
For information about NASA and agency programs, visit:
>>>www.ip.nasa.gov
June 9, 2007 at 7:05 am (News)
Search engine optimization (SEO) is the process of improving the volume and quality of traffic to a web site from search engines via “natural” (“organic” or “algorithmic”) search results. Usually, the earlier a site is presented in the search results, or the higher it “ranks,” the more searchers will visit that site. SEO can also target different kinds of search, including image search, local search, and industry-specific vertical search engines.
As a marketing strategy for increasing a site’s relevancy, SEO considers how search algorithms work and what people search for. SEO efforts may involve a site’s coding, presentation, and structure, as well as fixing problems that could prevent search engine indexing programs from fully spidering a site. Other, more noticeable efforts may include adding unique content to a site, and making sure that the content is easily indexed by search engines and also appeals to human visitors.
The acronym “SEO” can also refer to “search engine optimizers,” a term adopted by an industry of consultants who carry out optimization projects on behalf of clients, and by employees who perform SEO services in-house. Search engine optimizers may offer SEO as a stand-alone service or as a part of a broader marketing campaign. Because effective SEO may require changes to the HTML source code of a site, SEO tactics may be incorporated into web site development and design. The term “search engine friendly” may be used to describe web site designs, menus, content management systems and shopping carts that are easy to optimize.
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June 9, 2007 at 5:06 am (News)
In 2002 an eighteen-year-old Canadian newcomer named Avril Lavigne swept on to the U.S. music scene with her debut disc, Let Go. By the end of the year, three singles from the album, including “Complicated,” broke into the top ten of the Billboard charts, and Let Go was the second best-selling CD of the year. Lavigne’s music scored high with fans and critics, but so did her personal style, which consisted of wearing loose pants, tank tops, and neckties. As a result, she sparked a fashion trend and was heralded in the press as a “skater-punk,” an alternative to pop princesses, like Britney Spears (1981–), whose look and videos had started to become increasingly more provocative. In May 2004 Lavigne released her second album, Under My Skin, which debuted at number one not only in the United States, but also in many other countries, including Germany, Spain, and Japan. By the end of 2005 Avrilmania was showing no signs of slowing—Lavigne was performing to sold-out crowds on an extended concert tour and in April she took home top honors at the Juno Awards, which are considered to be the Canadian equivalent of the U.S. Grammy Awards.
Avril Ramona Lavigne was born on September 27, 1984, in Belleville, a small city in the eastern part of the province of Ontario, Canada. The second of three children, her father, John, was a technician for Bell Canada; mother Judy was a stay-at-home mom. When Lavigne was five, the family moved to Napanee, a farming town even smaller than Belleville with a total population of only five thousand. From the time she was a toddler Lavigne idolized her older brother, Matt, and insisted on trying to do anything he could do. As she explained to Chris Willman of Entertainment Weekly, “Ifhe played hockey, I had to play hockey. He played baseball, I wanted to.” In fact, when Lavigne was ten she played in the Napanee boy’s hockey league; she also became known as quite a baseball pitcher.
As she grew older Lavigne gained a reputation as a tomboy who preferred family outings like dirt biking or camping over dating. And in the tenth grade she discovered skateboarding, which became a particular passion. “I’m just not a girlie-girl,” Lavigne laughingly told Willman. When not playing sports, however, she did pursue another interest—singing. The Lavignes were devout Christians and attended Evangel Temple in Napanee, where young Avril sang in the choir beginning at age ten. Soon she branched out and began singing at all types of venues, including county fairs, hockey games, and company parties. She primarily sang covers of songs made popular by
“Why should I care what other people think of me? I am who I am. And who I wanna be.”
country singers Martina McBride (1966–) and Faith Hill (1967–). Lavigne’s parents bought her a sound machine to sing along with, and she practiced in front of a mirror at home for hours.
In 1998, when she was fourteen years old, Lavigne’s first manager, Cliff Fabri, discovered her singing at a small performance in a local bookstore. When talking to Willman, Fabri described the young girl as a “frizzy-haired waif.” But he liked Lavigne’s voice, and he was especially impressed by her confident attitude. That same year, such confidence helped her win a contest to sing a duet with fellow Canadian Shania Twain (1965–) at the jam-packed Corel Centre in Ottawa. Even though it was her first time performing in front of twenty thousand people, Lavigne was fearless. As she told Willman, “I thought, ‘This is what I’m going to do with my life.”‘
Two years later, when she was sixteen, Fabri arranged for Lavigne to audition for L.A. Reid, head of Arista Records in New York City. After a fifteen-minute tryout Reid signed Lavigne to an amazing two-record, $1.25 million contract. The sixteen year old immediately dropped out of high school to devote herselfto working on her first album. At first producers offered Lavigne new country tunes to sing, but after six months the team was unable to write any actual songs, and it became apparent that things were not clicking. Reid then sent the singer to Los Angeles to work with a team of producers and writers known as The Matrix. When Lavigne arrived in L.A. Matrix producer Lauren Christy asked Lavigne what style she had in mind. As Christy relayed to Chris Willman, Lavigne had responded, “I’m 16. I want to rock out.” That same day Lavigne and Matrix writers penned the first song for her album, “Complicated.”
June 9, 2007 at 4:51 am (News)
Nibiru is the 4th dimensional flagship of the Milky Way Galaxy’s Galactic Federation. Many different civilisations have representatives that live aboard it. It is a planet, a battlestar, and a ship, all at the same time. It was the main peacekeeping force in the galaxy until 2000 BC, and is a little over 3 times the size of Earth.
Nibiru’s symbol is the 8 pointed star. It is very bright due to the gold dust suspended in its atmosphere. It used to travel in the 5th dimension, but that changed when Marduk, grandson of Anu (the Pleiadean ruler of Nibiru) overthrew his grandfather and took command of the battlestar flagship. As a result of this turn of events, members of the higher councils of the Nibiruan Council decided to limit Nibiru’s ability to use stargates. Now Nibiru only has access to stargates in the 4th dimension.
Nibiru remains our trigger for awakening. When it returns to this solar system, uncloaks and shows itself, it will bring about a universal shift in consciousness. Mankind will then wake up to the fact that they are not alone in the universe, and will begin to search for the reason and purpose behind this great planet/ship. [The Vatican's secret service has been following Nibiru's progress via a secret link to the little known second Hubble Telescope for some time now. It came into our solar system following the ships disguised as HaleBopp comet. Nibiru is the star Wormwood of biblical Revelation.]
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