Vertical Take-Off and Landing craft have been the subject of military developers for some time. In addition to being able to deploy from landing strips that are damaged or small for conventional aircraft, they are also able to navigate terrain and land where other craft cannot. Add to that the ability to hover and fly close to the ground, and you have a craft that can also provide support while avoiding IEDs and landmines.
One concept that incorporates all of these features is the AirMule, a compact, unmanned, single-engine vehicle that is being developed by Tactical Robotics in Israel. In January of 2013, the company unveiled the prototype which they claimed was created for the sake of supporting military personnel, evacuating the wounded, and conducting remote reconnaissance missions.
Now, less than a year later, the company conducted a demonstration with their prototype aircraft recently demonstrated its ability to fly autonomously, bringing it one step closer to carrying out a full mission demo. During the test, which took place in December, the craft autonomously performed a vertical take-off, flew to the end of a runway, then turned around on the spot and flew back to its starting point.
All the while, it maintained altitude using two laser altimeters, while maintaining positioning via a combination of GPS, an inertial navigation system, and optical reference to markers on the ground. These autonomous systems, which allow it to fly on its own, can also be countermanded in favor of remote control, in case a mission seems particularly harry and requires a human controller.
In its current form, the AirMule possesses many advantages over other VTOL craft, such as helicopters. For starters, it weighs only 770 kg (1,700 lb) – as opposed to a Bell UH-1 empty weights of 2,365 kg (5,215 lbs) – can carry a payload of up to 640 kg (1,400 lb), has a top speed of 180 km/h (112 mph), and can reach a maximum altitude of 12,000 ft (3,658 m).
In short, it has a better mass to carrying capacity ratio than a helicopter, comparable performance, and can land and take-off within an area of 40 square meters (430.5 sq ft), which is significantly smaller than what a manned helicopter requires for a safe landing. The internal rotor blades are reportedly also much quieter than those of a helicopter, giving the matte-black AirMule some added stealth.
Plans now call for “full mission demonstrations” next year, utilizing a second prototype that is currently under construction. And when complete, this vehicle and those like it can expected to be deployed to many areas of the world, assisting Coalition and other forces in dirty, dangerous environments where landmines, IEDs and other man-made and natural hazards are common.
Alongside machines like the Alpha Dog, LS3 or Wildcat, machines that were built by Boston Dynamics (recently acquired by Google) to offer transport and support to infantry in difficult terrain, efforts to “unman the front lines” through the use of autonomous drones or remote-controlled robots continue. Clearly, the future battlefield is a place where robots where will be offering a rather big hand!
And be sure to check this video of the AirMule demonstration, showing the vehicle take-off, hover, fly around, and then come in for a landing:
Welcome everyone to my first special-request piece! As some of you who read this blog regularly may know, I was recently done a solid by a friend who brought the existence of my latest book (Whiskey Delta) to the attention of Max Brooks, Mr. World War Z man himself! Because of this, I told him he was entitled to favor, redeemable whenever he saw fit. Especially if the favor he did me allowed me to make it big!
Much to my surprise, he called it in early. Yes, instead of waiting for me to become a success and demanding 50 grand and pony, he asked that I do a tribute piece in honor of Israeli Independence Day, one that acknowledges the collective scientific, medical and technological achievements of this nation.
So hang tight. Not the easiest thing in the world to sum up an entire nation’s contributions in several fields, but I shall try. And for the sake of convenience, I broke them down into alphabetical order. So to my Israeli readers and those with family in the Levant, Shalom Aleichem, and here we go!
Aerospace: When it comes to space-based research, aviation and aeronautics, Israel has made many contributions and is distinguished as one of the few nations outside of the – outside of the major space players – that is able to build and launch its own communications, navigation and observation satellites. This is performed through the Israel Aerospace Industries(IAI), Israel’s largest military engineering company, in cooperation with the Israel Space Agency, which was created in 1982.
What’s more, Technion, the Israeli Institute of Technology, is home to the Asher Space Research Institute (ASRI), which is unique in Israel as a university-based center of space research. In 1998, the Institute built and launched its own satellite – known as the Gerwin-II TechSAT – in July 1998 to provide communications, remote sensing and research services for the nation’s scientists.
Israel’s first ever satellite, Ofeq-1, was built and launched using the locally-built Shavit launch vehicle on September 19, 1988. Over the course of its operational history, Ofeq-1 has made important contributions in a number of areas in space research, including laser communication, research into embryo development and osteoporosis in space, pollution monitoring, and mapping geology, soil and vegetation in semi-arid environments.
AMOS-1 and AMOS-2, which were launched in 1996 and 2003 respectively. AMOS-1 is a geostationary satellite that also has the honor of being Israel’s first commercial communications satellite, built primarily for direct-to-home television broadcasting, TV distribution and VSAT services. AMOS-2, which belongs to the Spacecom Satellite Communications company, provides satellite telecommuncations services to countries in Europe, the Middle East and Africa.
Additional space-based projects include the TAUVEX telescope, the VENUS microsatellite, and the MEIDEX (Mediterranean – Israel Dust Experiment), which were produced and launched in collaboration the Indian Space Research Organizations (ISRO), France’s CNES, and NASA, repsectively. In addition to conducting research on background UV radiation, these satellites are also responsible for monitoring vegetation and the distribution and physical properties of atmospheric desert dust over the a large segment of the globe.
Ilan Ramon, Israel’s first astronaut, was also a member of the crew that died aboard the Space Shuttle Columbia. Ramon was selected as the missions Payload Specialist and trained at the Johnson Space Center in Houston, Texas, from 1998 until 2003. Among other experiments, Ramon was responsible for the MEIDEX project in which he took pictures of atmospheric aerosol (dust) in the Mediterranean. His death was seen as a national tragedy and mourned by people all over the world.
According to the Thomson Reuters agency, in a 2009 poll, Israel was ranked 2nd among the 20 top countries in space sciences.
Alternative Fuel and Clean Energy: When it comes to developing alternative sources of energy, Israel is a leader in innovation and research. In fact – and due in no small part to its lack of conventional energy resources – Israel has become the world’s largest per capita user of solar power, with 90% of Israeli homes use solar energy for hot water, the highest per capita in the world.
Much of this research is performed by the Ben-Gurion National Solar Energy Center, a part of the Ben-Gurion University of the Negev (in Beersheba). Pictured above is the Ben-Gurion parabolic solar power dish, the largest of its kind in the world. In addition, the Weizman Institute of Science, in central Israel, is dedicated to research and development in the field of solar technology and recently developed a high-efficiency receiver to collect concentrated sunlight, which will enhance the use of solar energy in industry as well.
Outside of solar, Israel is also heavily invested in the fields of wind energy, electric cars, and waste management. For example, Israel is one of the few nations in the world that has a nationwide network of recharching stations to facilitate the charging and exchange of car batteries. Denmark and Australia have studied the infrastructure and plan to implement similar measures in their respective countries. In 2010, Technion also established the Grand Technion Energy Program (GTEP), a multidisciplinary task-force that is dedicated to alternative fuels, renewable energy sources, energy storage and conversion, and energy conservation.
Private companies also play a role in development, such as the Arrow Ecology company’s development of the ArrowBio process, which takes trash directly from collection trucks and separates organic from inorganic materials. The system is capable of sorting huge volumes of solid waste (150 tons a day), salvaging recyclables, and turning the rest into biogas and rich agricultural compost. The system has proven so successful in the Tel-Aviv area that it has been adopted in California, Australia, Greece, Mexico, and the United Kingdom.
Health and Medicine: Israel also boasts an advanced infrastructure of medical and paramedical research and bioengineering facilities. In terms of scientific publications, studies in the fields of biotechnology, biomedical, and clinical research account for over half of the country’s scientific papers, and the industrial sector has used this extensive knowledge to develop pharmaceuticals, medical equipment and treatment therapies.
In terms of stem cell research, Israel has led the world in the publications of research papers, patents and studies per capita since the year 2000. The first steps in the development of stem cell studies occurred in Israel, with research in this field dating back to studies of bone marrow stem cells in the early 1960s. In 2011, Israeli scientist Inbar Friedrich Ben-Nun led a team which produced the first stem cells from endangered species, a breakthrough that could save animals in danger of extinction.
Numerous sophisticated medical advancements for both diagnostic and treatment purposes has been developed in Israel and marketed worldwide, such as computer tomography (CT) scanners, magnetic resonance imaging (MRI) systems, ultrasound scanners, nuclear medical cameras, and surgical lasers. Other innovations include a device to reduce both benign and malignant swellings of the prostate gland and a miniature camera encased in a swallowable capsule used to diagnose gastrointestinal disease.
Israel is also a leading developer of prosthetics and powered exoskeletons, technologies designed to restore mobility to amputees and people born without full ambulatory ability. Examples include the SmartHand, a robotic prosthetic hand developed through collaboration between Israeli and European scientists. ReWalk is another famous example, a powered set of legs that help paraplegics and those suffering from partial paralysis to achieve bipedal motion again.
Science and Tech: In addition, Israeli universities are among 100 top world universities in mathematics (Hebrew University, TAU and Technion), physics (TAU, Hebrew University and Weizmann Institute of Science), chemistry (Technion and Weizmann Institute of Science), computer science (Weizmann Institute of Science, Technion, Hebrew University, TAU and BIU) and economics (Hebrew University and TAU).
Israel is also home to some of the most prestigious and advanced scientific research institutions in the world. These include the Bar-Ilan University, Ben-Gurion University of the Negev, the University of Haifa, Hebrew University of Jerusalem, the Technion – Israel Institute of Technology, Tel Aviv University and the Weizmann Institute of Science, Rehovot, the Volcani Institute of Agricultural Research in Beit Dagan, the Israel Institute for Biological Research and the Soreq Nuclear Research Center.
Israel has also produced many Noble Prize Laureates over the years, four of whom won the Nobel Prize for Chemistry. These include Avram Hershko and Aaron Ciechanover of the Technion, two of three researchers who were responsible for the discovery ubiquitin-mediated protein degradation in 2004. In 2009, Ada Yonath of the Weizmann Institute of Science was one of the winners for studies of the structure and function of the ribosome. In 2011, Dan Shechtman of the Technion was awarded the prize for the discovery of quasicrystals.
In the social sciences, the Nobel Prize for Economics was awarded to Daniel Kahneman in 2002, and to Robert Aumann of the Hebrew University in 2005. Additionally, the 1958 Medicine laureate, Joshua Lederberg, was born to Israeli Jewish parents, and 2004 Physics laureate, David Gross, grew up partly in Israel, where he obtained his undergraduate degree.
In 2007, the United Nations General Assembly’s Economic and Financial Committee adopted an Israeli-sponsored draft resolution that called on developed countries to make their knowledge and know-how accessible to the developing world as part of the UN campaign to eradicate hunger and dire poverty by 2015. The initiative is an outgrowth of Israel’s many years of contributing its know-how to developing nations, especially Africa, in the spheres of agriculture, fighting desertification, rural development, irrigation, medical development, computers and the empowerment of women.
Water Treatment: And last, but certainly not least, Israel is a leader in water technology, due again to its geography and dependence and lack of resources. Every year, Israel hosts the Water Technology Exhibition and Conference (WaTec) that attracts thousands of people from across the world and showcases examples of innovation and development designed to combat water loss and increase efficiency.
Drip irrigation, a substantial agricultural modernization, was one such developed which comes from in Israel and saved countless liters of farm water a year. Many desalination and recycling processes have also emerged out of Israel, which has an abundance of salt water (such as in the Dead Sea and Mediterranean), but few large sources of freshwater. The Ashkelon seawater reverse osmosis (SWRO) plant, the largest in the world, was voted ‘Desalination Plant of the Year’ in the Global Water Awards in 2006.
In 2011, Israel’s water technology industry was worth around $2 billion a year with annual exports of products and services in the tens of millions of dollars. The International Water Association has also cited Israel as one of the leaders in innovative methods to reduce “nonrevenue water,” (i.e., water lost in the system before reaching the customer). By the end of 2013, 85 percent of the country’s water consumption will be from reverse osmosis, and as a result of innovations in this field, Israel is set to become a net exporter in the coming years.
It’s hard to sum up the accomplishments of an entire nation, even one as young and as geographically confined as Israel. But I sincerely hope this offering has done some justice to the breadth and width of Israel’s scientific achievements. Having looked though the many fields and accomplishments that have been made, I have noticed two key features which seem to account for their level of success:
Necessity: It’s no secret that Israel has had a turbulent history since the foundation of the modern nation in 1948. Due to the ongoing nature of conflict with its neighbors and the need to build armaments when they were not always available, Israel was forced to establish numerous industries and key bits of infrastructure to produce them. This has had the predictable effect of spilling over and inspiring developments in the civilian branches of commerce and development as well. What’s more, Israel’s location in a very arid and dry region of the world with few natural resources to speak of have also demanded a great deal of creativity and specialized resource management. This in turn has led to pioneering work in the fields of energy, sustainable development and agricultural practices which are becoming more and more precious as Climate Change, population growth, hunger and drought effect more and more of the world.
Investment: Israel is also a nation that invests heavily in its people and infrastructure. Originally established along strongly socialist principles, Israel has since abandoned many of its establishment era practices – such as kibbutz and equality of pay – in favor of a regulated free market with subsidized education and health care for all. This has led to a successive wave of generations that are strong, educated, and committed to innovation and development. And with competition and collaboration abroad, not to mention high demand for innovation, this has gone to good use.
And with that, I shall take my leave and wish my Israeli readers at home and abroad a happy belated Independence Day! May peace and understanding be upon you and us all as we walk together into the future. Shalom Aleichem!
For those deeply concerned about internet security and privacy, the year of 2013 certainly opened with a bang. First, there was the news that a cyberspy ring – apparently operating out of Russia – had been spying on embassies, governments and research institutions around the world for the past five years using a virus dubbed “Red October”. This was back in January, when the Moscow-based antivirus firm known as Kaspersky Lab announced the discovery of the international intrigue.
Then, on Jan. 30th, the New York Times announced that they too have been the target of hackers, this time from China. In a statement released by the newspaper, the company claimed that Chinese hackers have been persistently attacking their publication for the last four months, infiltrating its computer systems and getting passwords for its reporters and other employees.
The timing of the attacks coincided with a Times investigation, published online on Oct. 25, that found that the relatives of Wen Jiabao, China’s prime minister, had accumulated a fortune worth several billion dollars through business dealings. The hackers tried to cloak the source of the attacks on The Times by first penetrating computers at United States universities and routing the attacks through them.
With the help of Mandiant, the internet security company hired by The Times, they were able track the intruders, study their movements and help erect better defenses to block them. In the end, The Times reported that they had successfully expelled the attackers and kept them from breaking back in. However, the fact these hackers were able to infiltrate the network of a private news organization in the first place was much cause for worry.
For one, this is not the first time that hackers, originating in China, have used these sort of subterfuge tactics to hack US databases. According to experts at Mandiant, their company has tracked many such intrusions back to the Chinese mainland, all of which used the same approach of cloaking their efforts using US servers. In addition, this incident, which smacked of state-involvement, did not occurr in a vacuum.
Back in 2008, internet security experts indicated that Chinese hackers had begun targeting Western journalists as part of a wider campaign to identify and intimidate their sources and contacts, and to anticipate stories that might damage the reputations of Chinese leaders. The purpose behind this far-reaching and growing spy campaign aimed at corporations, government agencies, activist groups and media organizations inside the US seemed to be for the purpose of controlling China’s public image, domestically and abroad, as well as stealing trade secrets.
But of course, China is hardly alone in these sorts of covert cyber-warfare. As already mentioned, Russia has already shown signs of developing cyber weapons to assist in spying abroad, and there’s mounting evidence that Israel, Iran and the US are on board too. Starting in 2008, Iran’s main nuclear enrichment plant was hit by a sophisticated computer worm that caused damage to it, thus putting a crink in their efforts to become a nuclear power.
While no one took responsibility for this incident, the evidence seemed to indicate that the worm originated from sources within Israel and the US. Attacks which took place later on American banks and oil companies within the US were believed to have been caused by Iran, in retaliation for the worm that hurt their main source of enriched uranium and a key component in their nuclear program.
For some time now, hacking federal databases has become something of a sport for various groups and causes who are seeking to reveal government secrets and expose their inner workings to public scrutiny. The “Hacktivist” group known as Anonymous is a perfect example, a group closely linked to Assange (of Wikileaks) who’s most recent infiltration of the Federal Reserve Bank made the news earlier this month as well.
But as I’m sure all will agree, it’s one thing when private citizen attack domestic and foreign databases, and quite another when nations attack each others. While cyber criminals may constitute a vague and slippery enemy, one which is much harder to identify and prosecute, nation-states constitute a far more frightening one. Not only are their resources far more vast, the consequences of battling them are far greater.
Knowing who your enemy is, and that they have nuclear capabilities and the ability to strike at you physically… Yes, I think that’s a much scarier prospect! While the old ways of plausible deniability and covert action may apply, no one likes the idea of subtle attacks which could escalate into a full-scale conflict. Even if it is waged entirely by computer, the effects are still likely to be felt!