วันพฤหัสบดีที่ 19 พฤศจิกายน พ.ศ. 2552
Apple Store, Fifth Avenue, New York
Unlike most Macintosh retailers that most of you see the glass retail space on the ground showing the beauty of Macs, iPods, and iPhones, the retail space is located UNDERGROUND!!!, and only part of the store above the ground is the glass cube. So, you can't see Macs, iPhones, and iPods demonstrators on the ground. You can see only Apple logo above, and the stairs are made by glass, and it's spiral, with a cylindrical glass elevator runs in the middle. So, you have to go down beneath the ground if you like to try a Mac or other Jobs' products.
Elevator ride from the basement to the surface. This elevator is made by Otis. Unlike most elevators found around us, this elevator is driven by hydro-electric system or what we call "Hydraulic".
The Apple Store Fifth Avenue is open 24 hours a day, 365 day a year, to offer you an unprecedented level of service and creative support.
2. Apple Store at Dawn
Wake up, morning glory. Nearly 300 highly trained Mac Specialists, Mac Geniuses and Creatives can help bring your creative projects to life.
3. Architecture
Apple’s most architecturally innovative store, Apple Store Fifth Avenue features a stunning, distinctive 32-foot glass cube entrance.
4. Genius Bar
The store has a combined 45-foot Genius Bar, iPod Bar and The Studio where customers can get support, free advice and work on creative projects.
5. Stairs
Make your entrance into the Apple Store in style, crossing the threshold of the glass cube and embarking down the glass staircase.
6. iPods and iTunes
Visitors can play with nearly 200 iPods on display and shop from the world’s largest assortment of accessories for the iPod and Mac.
Source: www.apple.com/retail/vr/
Weather cooled down so quick....
November 19th, 2009: 25 Celsius in the morning
This is really a dramatic change, that many of us can't adjust themselves to their proper homeostatic conditions. This causes illness to many people.
วันพุธที่ 18 พฤศจิกายน พ.ศ. 2552
Pigeons
Taxonomical classification:
Kingdom: Animalia
Phylum: Chordata
Class: Aves
Order: Columbiformes
Family: Columbidae
Genus: Columba
Species: C. Livia
More Information:
http://en.wikipedia.org/wiki/Rock_Pigeon
http://en.wikipedia.org/wiki/Columbidae
Above the locker in front of chemistry lab at my school during the rainy day.
In front of HM King Bhumibol's father's monument, Siriraj Hospital.
Red Blood Cell
Osmosis: Water will flow from solution with lower concentration to solution with higher concentration.
Therefore, osmosis makes water to flow from outside into the cell. Unlike plant cells, animal cells don't have cell walls, so they can't tolerate higher internal pressure, and finally burst. Hypotonic plant cells are turgid, which is its healthy state.
(The best condition of animal cell is isotonic condition)
Respiratory pigments in crustacean arthropods and many molluscs
Hemocyanin:
- Similar to hemoglobin founded in vertebrates.
- Found in arthropods (especially crustaceans) and many molluscs.
- In the form of metalloproteins containing two copper atoms that reversibly bind a single oxygen molecule (O2). (Makes the blood blue from Cu2+ ion)
- Colourless when deoxygenated. (The blood appears as grey-white to pale yellow, due to the tissue fluid.)
- Dark blue when oxygenated.
- Most hemocyanins bind with oxygen non-cooperatively and are roughly one-fourth as efficient as hemoglobin at transporting oxygen per amount of blood.
- In some hemocyanins of horseshoe crabs and some other species of arthropods, cooperative binding is observed, with Hill coefficients between 1.6-3. (Hemoglobin for comparison has a Hill coefficient of usually 2.8-3)
- In case of cooperative binding, hemocyanin was arranged in protein sub-complexes of 6 subunits (hexamer), each with one oxygen binding site.
- Binding of oxygen on one unit in the complex would increase the affinity of the neighboring units.
- Hemocyanin oxygen-binding profile is also affected by dissolve-salt ion levels and pH.
- Hemocyanin oxygen transportation is more efficient than hemoglobin oxygen transportation in case of an animal that live in the cold environments and low oxygen pressure condition. (where several important marine invertebrates such as shrimps, crabs lives)
วันจันทร์ที่ 16 พฤศจิกายน พ.ศ. 2552
Failed hackintosh laptop; switching hackintosh to desktop
THE HIGH ALTITUDE LIFE
Lily Whiteman, Washington DC
Bar-headed geese (Anser Indicus) migrate over Mount Everest, where oxygen is scarce and life is rare. How do they survive in such conditions?
At 29,028 feet, Mount Everest is tall enough to poke into the jet stream, a high-altitude river of wind that blows at speeds of more than 200 miles an hour. Temperatures on the mountain can plummet low enough to freeze exposed flesh instantly. Its upper reaches offer only a third of the oxygen available at sea level--so little that if you could be transported instantly from sea level to Everest's summit, without time to acclimatize, you would probably lose consciousness within minutes. Kerosene cannot burn here; helicopters cannot fly here. Yet every spring, flocks of bar-headed geese--the world's highest-altitude migrants--fly from their winter feeding grounds in the lowlands of India through the Himalayan range, sometimes even directly above Everest, on their way to their nesting grounds in Tibet. Then every fall these birds retrace their route to India. With a little help from tailwinds, they may be able to cover the one-way trip--more than 1,000 miles--in a single day.
Considering the bar-headed goose's stamina and tolerance for thin air, one might expect this bird to take the form of a giant lung. But it doesn't. Rather, its robust gray body, long neck (the most notable characteristic that distinguish geese from ducks, in the same family, Anatidae), and short, tapered beak create an elegant S-shaped silhouette. Adults weigh about five pounds and stand about two feet high. Two horizontal black stripes on the back of the bird's white head give the species its name.
The yearly migration of these geese is apparently triggered by a biological alarm that rings early enough in the spring for them to miss the summer monsoon season and early enough in the fall for them to miss the worst of winter's storms. Still, they cast their fates to the wind only with due consideration. Geese poised to take off, for example, may delay their flight if strong headwinds kick up. And when airborne birds get tossed about, they may turn back and land or change altitude in search of better conditions.
Moreover, by using tailwinds, the geese capitalize on weather that could pulverize lesser creatures. "These birds are powerful flappers, not soarers that just glide with the wind," says M.R. Fedde, an emeritus professor of anatomy and physiology at Kansas State University's School of Veterinary Medicine, who has conducted laboratory studies of the bar-headed goose's respiratory system. Partly because their wings are huge, have a disproportionately large surface area for their weight, and are pointed to reduce wind resistance, "they can fly over 50 miles an hour on their own power," Fedde says. "Add the thrust of tailwinds of perhaps 100 miles an hour if they are lucky, and these birds really move." Able to gauge and correct for drift, bar-headed geese can even fly in crosswinds without being blown off course. The same powerful and unremitting flapping that helps propel them over the mountains also generates body heat, which is retained by their down feathers. This heat, in turn, helps keep ice from building up on their wings.
What's the secret to the bar-headed goose's aerobic success? "First of all, bar-headed geese are birds," says S. Marsh Tenney, an emeritus professor of physiology at Dartmouth Medical School, whose research on respiratory adaptations to oxygen deprivation includes studies of these highfliers. "And all birds are built for particularly efficient oxygen uptake." The avian breathing system is uniquely structured. Among its special features are air sacs that temporarily store inhaled air that has passed through the lungs and then send it back through their lungs before it is exhaled. Thus, birds circulate inhaled air through their lungs twice--once more than earthbound mammals do--increasing their opportunities for capturing oxygen.
Birds can also pant for prolonged periods without constricting the blood vessels in their brains. So even when physically taxed, they keep their wits about them. By contrast, prolonged panting in people reduces blood flow to the brain, which primes them for bad decision making--hence the occasional unfortunate climber who blithely strolls off a cliff.
Bar-headed geese are "super birds," says Tenney. "They do everything even better than other birds." They have a special type of hemoglobin (open hemoglobin; higher oxygen affinity than “closed” hemoglobin in humans; even though avian RBCs have nuclei, lesser surface area than mammalian RBCs) that absorbs oxygen very quickly, combining with high RBC density per blood volume and the unique lungs and “air sacs”, one of the trademark of avian as described in last two paragraphs, that enable bar-headed geese to take in oxygen twice in only single breathing cycle, making absorption of oxygen even quicker at high altitudes. As a result, they can extract more oxygen from each breath of rarefied air than other birds can. Once their blood is stoked with oxygen, it rushes through capillaries that penetrate particularly deep into their (flight; pectoral) muscles, which is very rich in “red” fibers that is biologically designed for sustained contractions and relaxations with lesser fatigue in long exercising durations, one of the trademarks of “avian migrants”, with thanks from aerobic respiration. Thus energized, their wings flap with seemingly inexhaustible vigor. Other migratory birds, without the superior flapping, respiratory, and circulatory power of the bar-headed goose, fly closer to the ground. Most songbirds, for example, fly at between 500 and 2,000 feet, and most waterfowl stay between 200 and 4,000 feet.
The awesome engineering of the bar-headed goose's body aside, the logic behind its migratory route remains baffling. After all, the cold, high desert of Tibet, which offers few productive ponds, hardly seems to be a breeding ground worthy of death-defying journeys, even by such tough birds. Moreover, the geese reject much lower routes between India and Tibet that slice through the Himalayas only several miles from their high-altitude flyways. One explanation for this behavior was advanced by the late Lawrence Swan, an explorer and a biology professor at San Francisco State University. One evening during a Himalayan expedition, he was startled by the honking of night-flying bar-headed geese passing directly over Mount Makalu's 27,824-foot summit. This experience caused Swan to speculate that the species had originally settled in India before collisions between the tectonic plates under the Hima-layas had pushed the range up.
Watered by melting ice-age glaciers and without the shadow later cast by the Himalayas, ancient Tibet may have been a land of green valleys and summer lakes and streams, according to Swan's theory. Such a landscape could have drawn bar-headed geese for seasonal visits. The mountains presumably rose slowly enough to accommodate evolution, so these geese could have continued to fly their customary routes while adapting to the altitude. Each new generation probably learned the route by traveling in flocks with its elders during its first year and then taught it to its own offspring in later years. The species would have thus perpetuated its flyways through the ages. If, indeed, bar-headed geese are "older than the hills below them," as Swan believed, their current migrations remain a "behavioral fossil" from early Himalayan Asia.
Swan also speculated that the summits provided bar-headed geese with more obvious landmarks. In addition, only at high altitudes can the birds catch the fastest tailwinds, which blow far above the earth's obstacles. Other explanations suggest that high flyways actually save the goose both time and energy, compared with longer routes that circumvent the mountains.
Although no one knows for sure how migrating birds navigate, most scientists suspect that they follow a combination of cues--tall peaks and other geographic features, such as rivers; the position of the sun and the stars; geomagnetic signals; and changes in barometric pressure. The honking of bar-headed geese during flight may convey messages that help flocks stay together, and may also create orienting echoes.
Despite an abundance of theories about the behavior and the biology of bar-headed geese, their true strength has yet to be measured, let alone fully understood. Since their remote habitat has precluded the comprehensive study of the geese, most current information about their physiology has been gleaned from individuals that were monitored while resting or waddling on treadmills. Though such research offers insights, bar-headed geese have still never been studied while flying, says Kansas State's Fedde. "We could analyze bar-headed geese while they fly in wind tunnels," he says. "Or, like the geese portrayed in the movie Fly Away Home, they could be imprinted to follow an ultralight airplane while we measured their responses with portable monitoring equipment. But so far, funding for those sorts of studies just hasn't been there."
Scientists believe that better data on the physiology of bar-headed geese could ultimately help people cope with altitude and respiratory diseases. Frank Powell, a professor of medicine and the director of the University of California's White Mountain Research Station, a high-altitude field laboratory in Bishop, California, says, "We will never be able to engineer a human lung to work like a bird lung. But with more information we might be able to develop drugs that would help duplicate some of their cellular responses."
Other High-Altitude Creatures
Bar-headed geese are not alone at the top of the world. Several kinds of birds and one spider also frequent this rare-fied atmosphere. Living at 22,000 feet on Mount Makalu are jumping spiders, the highest known full-time land dwellers, says John Edwards, a professor of zoology at the University of Washington and an expert in high-altitude insects and spiders. Remarkably, these denizens of the heights are hardly different from the varieties of jumping spiders that populate backyard gardens at sea level. In fact, the spiders of Makalu lack "any obvious adaptations for life under such rigorous conditions," according to a report by F.R. Wanless, an invertebrate researcher at the British Museum and one of the few scientists to ever study these remote creatures.
Several other bird species regularly brave extreme altitudes. Among them are whooper swans, which were once observed by a pilot at 27,000 feet over the Atlantic Ocean between Iceland and the European continent, and bar-tailed godwits, which have been spotted at almost 20,000 feet. And then there's the occasional hardy individual that makes a high-altitude cameo.
The highest-flying bird ever recorded was a Ruppell's griffon, a vulture with a wingspan of about 10 feet; on November 29, 1975, a Ruppell's griffon was sucked into a jet engine 37,900 feet above the Ivory Coast--more than a mile and a half higher than the summit of Mount Everest. The plane was damaged, though it landed safely.
In 1924 a yellow-billed chough, a crowlike bird that's among the highest-nesting species, followed a climbing expedition's food scraps to 26,500 feet on Everest. The avian altitude record in North America is held by a mallard, which collided with an airplane on July 9, 1963, at 21,000 feet above Elko, Nevada.
Question
Explain briefly why some bar-headed geese are able to be very metabolically active at altitudes over 35,000 feet without any assisting device, even though they have red blood cells that have less surface area than mammalian red blood cells?
วันพฤหัสบดีที่ 12 พฤศจิกายน พ.ศ. 2552
Mitosis
There are 4 phases as described below, Prophase, Metaphase, Anaphase, Telophase. You can use the short term PMAT for easy memorization.
P: PROPHASE, PROMETAPHASE:
During chromosome duplication, several "bubbles" open up along the chromosome. Each bubble grows until it merges with an adjacent bubble. Each chromosome now consists of two identical copies called sister chromatids. Getting closer, we see that each sister chromatid consists of DNA wound around small proteins called histones. The sister chromatids begin to coil into tight helical fibers. Outside the nucleus, centrosomes that duplicated earlier move away from each other. Microtubules extend from the centrosomes, forming the mitotic spindle. Back in the nucleus, the DNA forms loops, becoming more compacted. These structures fold back on themselves eventually condensing into a shorter and thicker chromosome consisting of two sister chromatids. As the chromosomes continue to condense, the nuclear envelope breaks up. The array of spindle microtubules is now extensive and the chromosomes are fully condensed. Spindle fibers from each pole attach to protein structures located at the centromere of each sister chromatid. As the chromosomes are bound by spindle fibers from opposite poles, they move first one way and then another.
M: METAPHASE:
The counteracting forces of the spindle eventually cause all the chromosomes to end up at the center of the cell, as if arranged on an imaginary plate.
A: ANAPHASE:
The sister chromatids are released from each other, each becoming a full-fledged chromosome. They are moved toward opposite poles of the cell, pulled along the spindle fibers attached to them. At the same time, overlapping spindle fibers that are not attached to chromosomes continue to lengthen, pushing the poles farther apart.
T: TELOPHASE & CYTOKINESIS
Once the chromosomes arrive at their destination, they become less condensed. Two new nuclear envelopes form, completing mitosis, the division of one nucleus into two genetically identical daughter nuclei. The cytoplasm divides by the process of cytokinesis, forming two separate daughter cells. In your body, millions of cells divide every second, providing new cells for growth and for repair of damaged cells.
(C) 2007, Pearson Education
My Hackintosh Laptop (OSx86)
Sometimes you can call this thing as "HackBook", "HackBook Pro", or "HackBook Air", depending to the equivalence in specifications with Apple's MacBook, MacBook Pro, and MacBook Air respectively.
Steve Jobs, Apple's CEO, announced in WWDC2005 keynote address that it will switch the processors in its Macintosh computer lineup from PowerPC to Intel Processor. Steve Jobs decided to do this because of the "Performance-Per-Watt" reason that the future roadmap of Intel processors gives out higher performance at the equivalent power consumption than PowerPC. I think that he spoke the right thing because in my computer that I am using, it has Intel Core 2 Duo, which gives out great performance, while it takes less energy and lesser heat than my old Pentium 4. All Macintosh computers except the workstation Mac Pro and quad-core version of 27 inch iMac use Intel Core 2 Duo, which means that Apple uses the hardware in its Macs like the PC hardware, but only the difference is the TPM chip and EFI bootup system.
Once Apple changes to Intel platform, this means that Mac OS X runs on X86 architecture like PC that runs Windows, Linux, or FreeBSD. This means that Mac OS X can theoretically runs on PC without modifications, except additional bootloaders and kernel hacks if that PC uses Intel Core 2 Duo, which is the same as 5 of 6 Mac lineups.
Mac OS X is designed to run on the hardware that the same company (Apple) makes which are at a price premium compared to third-party hardware at the same specs. However, in OS X version 10.5.x license agreement, it said that, "You agree not to install, use
or run the Apple Software on any non-Apple-labeled computer, or to enable others to do so." This means that it's illegal to install OS X on PCs, but in Thailand, my country, doesn't strict about copyrights and licenses like Europe (requires agreement BEFORE purchasing), US, and other major developed regions. So, I would like to try to run OS X on my Acer Aspire 5920G laptop, and compare with Windows in terms of general performance.
Hardware inside my laptop
My laptop that is hackintoshed has these specs:
2.0 GHz Intel Core 2 Duo (T7300)
2 GB RAM
160GB Seagate ST9160820AS
nVidia GeForce 8600M GT
15.4 inch LCD screen, 1280x800
DVD Burner
VGA Webcam
Bluetooth 2.0+EDR
Intel WM3945BG wireless connection
Broadcom Gigabit LAN
Modem
4 USB Ports
HDMI Port
S-VIDEO out
VGA out
For this specs, I would like to call it HackBook Pro because it is comparable to MacBook Pro from Apple.
I used the OS X installation disc downloaded from BitTorrent, and what I used is from Leo XxX team, a hacked version of OS X 10.5.6. When I installed, it lacks several drivers, so I used iPC installation disc as a driver disc, and downloaded several drivers from InsanelyMac, OSx86 website.
After the installation, the system works very well like a clone of MacBook Pro, but some hardware doesn't function: Ethernet, Wi-Fi, card reader, and webcam, but these I don't use them a lot. However, I am finding in InsanelyMac in order to find fixing problems method, and I hoped that this will work fully as a real Mac soon.
I installed MS Office:Mac 2008, iWork 09, iLife 09, Final Cut Express 4, Aperture, Photoshop CS4, Acrobat 9.0, and some other applications, and they work well.
I think that why Apple have to tie its OS X to its hardware?
Startup versus MacBook Pro 13 inch video