Saturday, April 2, 2016

Electrical systems & adapting.

Electrical Systems Banner.jpg

Electrical systems differ around the world - both in voltage and less critically, frequency. The physical interface (plugs and sockets) are also different and often incompatible. However, travellers with electrical appliances can take a few steps to ensure that they can be safely used at their destination.

Voltage and frequency.

Start by taking a look at the back of the device you want to use. If it says something like "100-240V, 50/60 Hz", it will work anywhere in the world with the right plugs. If you've got both covered, you can skip to the next section. If not, keep reading.
Dealing with electricity differences can be daunting, but it actually isn't too hard. There are only two main types of electric systems used around the world, with varying physical connections:
  • 100-127 volt, at 60 hertz frequency (in general: North and Central Americas, Western Japan)
  • 220-240 volt, at 50 hertz frequency (in general: the rest of the world, with some exceptions)
Occasionally, you will find 100-127 volts at 50 Hz, such as in TokyoMadagascar, and some Caribbean islands. On the other hand, there's 220-240 volts at 60 Hz, such as in South KoreaPeruPhilippines some states of Brazil and Guyana. A few other countries using 60 Hz are internally divided, with 100-127 volts in some locations, and 220-240 volts in others, such as in Brazil, Some areas in thePhilippines, and Saudi Arabia. Be extra careful each time you travel to a new destination within these countries, and ask about the voltage. Be aware of multiphase electrical systems (see below under Large Appliance Power).
If the voltage and frequency for your device is the same as where you are travelling, then you need to worry only about the physical plug. (The small difference between 110V and 120V is within the tolerances of most electrical devices. Likewise for 220V and 240V.)
If the voltage provided by the local supply is not within the range accepted by your device, then you will need a transformer or converter to convert the voltage. Most travel accessory sources offer them and come with several plug adapters to solve all but the most exotic needs.

Plugs and adapters.

A device that lets you insert a plug into a different socket is an adapter: these are small, cheap and safe. For example, between Britain and Germany, you need only an adapter. You stick your British plug in the adapter, which connects the rectangular phase/live and neutral prongs to the round German ones and puts the ground where the German outlet expects it. Then, you're good to go.
Unfortunately, there are many different plugs in the world. The three most widespread standards are the following:
  • The "American" (Type A or B) plug, with two vertical pins
  • The "European" (Type C or F) plug, with two round pins
  • The "British" (Type G) plug, with three rectangular pins
If your device has one of these plugs and you can adapt it to the others, you have 90% of the world covered. (The main exceptions are South AfricaAustraliaNew ZealandArgentina, and parts of China, which use a Type I plug with two slanted pins.) Adapters between Type A and Type C and from C toG are tiny and cheap; converting Type A into G or Type G into anything else, on the other hand, needs a bulkier model.
For hobbyists: if you can't find an adapter, and you're staying for a longer time, just buy a separate plug at your destination, remove the existing plug, and attach the new one. Unlike adapters, plugs are always available, and they're generally cheaper too. Caution: try this only if you know what you're doing! (Fire and/or electrocution are possible if you are inexperienced.)
As a last resort, a Type C plug can be forced into a Type G socket without any converter at all if you ignore what your mother told you and stick a pen or similar pointy object into the center (ground) hole, which fools the socket into thinking a ground pin has been inserted and opens up the other holes. (This is, in fact, exactly what cheap C-to-G adapters do.) Disable the power to the socket and try to use something non-conductive (a dry non-metallic object) to do this! This procedure will damage the socket and could be unlawful in some countries, so expect the owner to be displeased.
There's one more complication to consider: any two-pin socket is ungrounded, but all three-pin plugs are grounded. Trying to get grounding to work makes life more difficult, as any of sockets C, D, E, F, H, J, K or L will happily accept the ungrounded plug C but will not work with any grounded variant other than their own. Do not use an adapter to turn a three-pin into a two-pin: this will disable grounding, potentially leaving you vulnerable to electrocution and other electrical nastiness.
A last word of warning: many developing countries use multi-plug sockets that accept (say) both Type A and Type C. Don't assume the voltage is correct just because the plug fits, since a Thai Type A+C socket still carries 220V and may destroy American (110V) Type A devices.


Transformer or converter?

If you are using a 220V-240V appliance at 110V, you will need a transformer.
If you are using a 110V appliance at 220V-240V, you can also use a transformer but may be able to get away with a (cheaper) converter.
If your device is an electric appliance with a heating element or mechanical motor such as an iron or hair-dryer, then you can probably just use a converter, but make sure your transformer or converter is fully rated to deliver the amps and watts your device needs. If your device is electronic and uses electronic chips or circuits, such as a computer, printer, TV, microwave, VCR or even a battery charger, you will need a transformer.
Before you purchase what you believe is your solution, understand the discussion below.

Transformers[edit]

  • They have two different types: "step-up" and "step-down". Step-up transformers allow you to plug a higher-voltage device into a lower-voltage power socket (such as using a UK device in the US). Step-down transformers allow you to plug a lower-voltage device into a higher-voltage socket (such as using a US device in the UK). Some transformers offer both. Take care to use the right type: if you plugged a 110-to-220 V step-up transformer into a 220 V socket, you would get 440 V and a fried device.
  • You must also make sure that the power rating (wattage) of your transformer is at least 10% greater than that of the device; otherwise, the transformer can overheat and even catch fire. Before buying a transformer, look for the "input" figure: usually on the device's plug or in the manual. Some don't display wattage, but you can work it out simply by multiplying the voltage (V) and the current (amps (A); if it is miliamps (mA), divide by 1,000). The resulting figure is the same as the wattage.
  • Transformers can be used with both electronic devices (such as those with chips and circuits) or electrical appliances (such as those with heating elements and motors). They can usually operate for a much longer time than converters.

Converters[edit]

These lighter-weight, less expensive devices can handle large wattage loads of up to 1600 watts but only step-down voltage, not raise it. They are suitable for those in 110-120V countries traveling to where the voltage is 220-240V. Converters are designed to operate for only an hour or two at a timenotcontinuously. As stated above, they cannot be used with electronic devices: devices that use chips or circuits, such as a computers, printers, VCRs ,or even battery chargers.
Nowadays, many electronic devices actually come with a converter which plugs into the power mains and converts the current to DC. However, if this won't accept a foreign voltage (check the plug) do not place a second converter behind it. You must use a heavier transformer instead. Fortunately, in the past few years, more and more devices come with a universal AC/DC converter already included, and the most you would need is a plug adapter.

Frequency (Hz)[edit]

Frequency is generally not a problem--most travel items will work on either 50 or 60 Hz. If all the electrical appliance does is produce heat or light (except fluorescent lighting), then the frequency is unlikely to matter.
Frequency is most likely to affect clocks and devices with motors. They may run faster or slower than they should and may be damaged in the long run as a result. Again, though, some motorised devices may function correctly on either 50 or 60 Hz-- especially if they also operate on batteries. Just look on the label or plug.
However, you still may need to be careful if you have a sensitive or expensive device that converts AC (power from the wall) into DC (battery-like current)--especially if you also need to convert the voltage. A device will convert AC to DC either to save battery power by allowing you to plug into the mains or charge a battery in the device. The design of power supplies where AC is converted into DC does take frequency into account.
Even though 60 Hz converts a little more easily to DC than 50 Hz does, there's enough tolerance in most small appliances and electronic gadgets that you can ignore frequency. However, if you also need to change the voltage (because the voltage of your device is different from the mains power voltage), you cannotuse a switching-type converter. You must use the heavier iron-core transformer. If in doubt, consult a reputable electrical goods dealer.
If your device won't operate with a different frequency (powerful motors and non-quartz clocks), there is really nothing you can do to change it. Unlike voltage, frequency cannot easily be converted. Foreign embassies may have to use huge generators to provide current compatible with equipment from home.
If you desperately need to have power at your home country's frequency, you might try using a 12V DC to AC converter intended for vehicle use. However, most of these (especially those commonly found in stores) output a "sawtooth" wave instead of a sine wave. (Check the manufacturer's website if you need a sine wave output. It may be special order.) Make sure the wattage of the converter is sufficient for whatever device you need to operate, and the 12V battery has enough amps for the job. For example, 12V times 15 amps gives 180 watts (or less after losses are included).
Japan is a special case. East Japan (eg Tokyo) uses 50 Hz and west Japan (eg Osaka) uses 60 Hz. Equipment made for the Japanese market may have a switch to select 50 Hz or 60 Hz.

Unstable supply[edit]

In many developing countries, electrical supply is highly erratic and you need to take precautions to protect your equipment.
The main danger is power spikes, where the voltage supplied temporarily surges to dangerous levels, with potentially catastrophic consequences. In developed countries, the main source of spikes is lightning strikes, but, in developing countries, they're most often associated with power outages since when the power comes back on, it rarely does so smoothly. The cheapest method of protection is thus simply to disconnect electronic devices as soon as the power goes out and wait a few minutes after the power comes back on until plugging them back in.
Surge protectors are devices designed specially to protect against spikes and surges, and some are available in portable travel-sized versions. Some surge protectors can also be fitted to a telephone line to protect your phone or laptop modem. The most common variety use a metal oxide varistor (MOV), which shorts to ground if a given voltage is exceeded. These are easily destroyed by larger spikes, and better models will have a light indicating when the MOV has broken down, but you still need to keep an eye on them as the device will still continue to give power even if the protection is gone. There are also surge protectors with fuses, which are fail-safe (a blown fuse will stop power) and replaceable, but there is still a risk of a short, sharp spike which can pass through and damage your device before the fuse blows.
In some (mostly poor) regions, you may experience electricity voltage drops. Instead of 240V for example, you may get only 200V or even less (50% of the nominal supply voltage is not unknown). This happens especially if you're at "the end of the line" (far from the source or transformer) and is caused by the resistance of the electric lines themselves. Some appliances, such as light bulbs and heating equipment just keep working under a lower voltage, although a 20% voltage drop will cause a 36% power drop. Most electronic devices also keep working, but voltage drops are critical for fluorescent lamps, refrigerators, and air conditioners which may stop working altogether (usually without being damaged: when the voltage returns to normal, they will start working again).
Voltage drops can be solved with a special device called a voltage stabiliser or AVR (Automatic Voltage Regulator). A stabiliser will raise the voltage again to its normal level. The principle is the same as for switching converters, except that stabilisers will produce a stable output, even with an unstable input. Stabilisers come in different power ranges, but they're all large, bulky and not practical to carry around. Be aware that some appliances, such as refrigerators, briefly consume 2 or 3 times more power at start-up; the stabiliser should be able to provide this power. Voltage stabilisers can introduce surges if there is a power outage. The cheaper and most common relay type can also damage electronic equipment.

Appliances[edit]

If you are buying new appliances, get in the habit of checking the voltage. A dual-voltage hair straightener will cost you no more than a single voltage one, and save considerable hassle when travelling.

Laptop computers[edit]

Virtually all laptop computers (including those with internal power supplies) will handle well a range of 100 to 240 volts and a frequency of 50 to 60Hz. In other words, you won't need a converter/transformer; most power supplies have supported ranges printed directly on them so have a look. You will still need to check that you have the plug that matches the outlet for the country you are going to to see if you need to buy an adaptor.
Laptop computer power supplies are generally very good at accepting a poor or varying supply. Many manufacturers use the same type of supply, so getting spares is not too hard. The type used by HP/Compaq is very common. It is very easy and cheap to get a spare supply from sites such as Ebay. However, make sure it is a genuine manufacturer replacement and not a cheap copy. With a spare, you can take a risk with an unknown supply. Of course, do not take any risks if your laptop is one of the few with an internal supply.
If you are taking a laptop, you can use it to charge other items using a USB port on the laptop, even if they are normally not connected to it - this can save you a bundle of transformers in your luggage. Just make sure you have the correct USB cable - there are many different types.

Radios[edit]

Radios also tend to be interchangeable from country to country. The exact FM range being used in a few countries is different, so you may not be able to access all stations. In the US, only odd channels (88.1,88.3, 100.1 etc) are used. A radio intended exclusively for the US market will not work well in most other countries. Japan, in particular, has an FM band from 76 MHz to 90 MHz rather than the more common 87.5 MHz to 108 MHz. The countries of the former Soviet Union have also used a similar band. For the medium wave band, channel spacings (the difference between each valid frequency) can be 9kHz or 10kHz (for USA). Some digital radios will have a switch or setting to choose which channel spacing is used. Without this, they will not work correctly outside their intended market. Old-fashioned analogue dial tuners don't have this limitation.
If you need a new radio for international travel, consider one that includes the shortwave band (SW). This way, you can receive news and information from all over the world (BBC, CBC, Voice of America, Radio Australia, etc.) Shortwave is above the medium wave band (in frequency terms), but travels a lot further, especially after dark. In the past few years, the size and price have come down considerably for AM/SW/FM radios, and they are much easier to use. A handful of stations now require the single sideband (SSB) function (normally used by hobbyists for voice communication), but for most people it's not essential.

Digital Radio[edit]

Digital radio is in use in some countries, but has generally not attracted large audiences. So radio listening remains a predominantly analogue world, unlike television. The most common systems are DAB (Europe), DAB+, DRM and HD Radio (US). For travellers, an analogue radio (especially those with digital displays) are the best choice.

Mobile phones and digital cameras[edit]

Chargers for these may work with both 110V and 240V systems, though you may still need an adaptor plug or have to use the shaver socket. You may be able to get a second charger for the other voltage system, or even a dual voltage charger designed for both systems. However, your mobile phone handset may not be compatible with the country's network, or you may be limited to certain cellular providers. (See Telephone service for travel#Cell phones.)

Equipment using standard batteries[edit]

Battery sizes and voltages tend to be standard from place to place, and equipment that uses off-the-shelf batteries tends to be interchangeable. It may be difficult to get good quality batteries in some countries, especially alkaline batteries which are needed by most electronic equipment. If a cheaper battery is used, make sure to remove it as soon as it is exhausted or if the equipment will not be used for a while due to the risk of leakage.
Dual voltage battery chargers for NiCad and NiMH generally cost no more than single voltage ones, but you need to look for this feature before you buy. If an existing single-voltage charger uses a 12 volt DC adapter, find a quality dual-voltage adapter (110V - 240V) at 12 Volts DC with its DC current rating (inmilliAmps) equal or higher, and the same size plug on the charger end. (This is not possible if the charger plugs directly into the power mains without any cord.)

Be cautious[edit]

Large appliance power mains (Single, split phase or three phase supply)[edit]

In most countries, electrical power is distributed using a three phase system. This means that there are 3 different live/phase wires and optionally a single neutral wire. Domestic outlets are invariably single phase. A domestic outlet will receive just one of these phase wires and a neutral wire. Depending on the country, a mains supply into a residential building may be a single phase supply or three phase supply. Most larger buildings will receive a three phase supply.
There are good reasons why electricity networks use 3 phase supplies. They are also most appropriate for running large machines with motors (large air conditioners, industrial/commercial ovens and other power hungry appliances). The voltage between any one of the three phases and neutral is the same as the domestic single phase out let voltage (110V, 230V, 240V etc). However, the voltage between two phase wires is typically 380-415V or 208V in a 110V single phase system.
In North America there is a further variation, the split phase system. In the split phase system, two phase wires are used, but the voltage between these wires is double the single phase voltage - 240V. These systems are used to run large appliances such as cookers. However, it is also not uncommon to use two of the phase wires from the three phase system to give 208V.
In some places (mostly industrial buildings) three phase outlets may be available (often coloured red). Adapter cables or plugs can be used which take one of the phase connections and neutral for standard single phase appliances. Regardless of how many phases are in use, the frequency (50Hz or 60Hz) of the supply remains unchanged.
In countries with a poor distribution network, it is not unknown for single phase sockets to be connected across 2 phases to boost the voltage. This is dangerous and can damage electronic equipment. As a general rule, do not attempt to connect your personal electrical items to a socket or wiring system that is a three phase system.

Generators[edit]

In many countries without fully developed electrical power distribution systems, the use of generators is common. Generator supplies can be very good; however, in many places they are bad and can cause damage to sensitive equipment connected. The voltage, frequency, and waveform shape (it should be a smooth sine-wave) can vary. In some places, people modify generators to run faster. This gives more voltage and power but increases the frequency too. The part of a generator that keeps it running at a constant speed is called the governor. If this is tampered with, the output voltage could rise sufficiently to cause damage. The best advice is not to connect valuable equipment to the supply, or at the very least disconnect it as soon as you're finished.
If you are unsure about the quality of the generator in use, there are a few simple rules. If it runs from petrol/gasoline, it is bad: anyone serious about using generator power uses a diesel oil powered system. A good quality generator will have a low engine speed. 1500RPM for 50Hz or 1800RPM for 60Hz. If the engine speed is 3000RPM or more, it is not a good machine.

Lamps[edit]

Lamps and their light bulbs are very sensitive to voltage. If you shift between voltage systems, you will need to change the light bulbs to match the voltage, unless the lamp is designed to operate on both systems, say through a low voltage adaptor. If you buy a lamp abroad, you may need to have an electrician completely rewire a lamp when you get home to comply with your country's electrical safety standards. This may not be a problem for a one-off special item, but if you are going into the importing business it could be a showstopper.
Also watch out for the light bulb connection. In 100-127V systems this is often a screw connector while in 220-240V systems it is often a bayonet connector. These connectors also come in at least two different sizes. Be sure you can obtain light bulbs of the right voltage, size, and connector shape in the country you intend to use the lamp, and at a reasonable price, or the lamp may become little more than junk when the bulb fails.
Note that fluorescent and LED lighting contains electronics and must use a heavy iron-core transformer to convert voltage. Converters are not acceptable. Some fluorescent units might be sensitive to changes in frequency (50 or 60 Hz) if it's not the same as what is specified. This type of lighting has its own "flickering" frequency, which is suppose to be too rapid to notice. However, old and defective units often produce an annoying, visible flicker, and the wrong electrical frequency might have the same effect as well.

Electric motors[edit]

The electric motors in things like refrigerators, vacuum cleaners, washing machines and other whiteware are often sensitive to frequency. Older hairdryers and electric shavers might be also. Even if you use a step-up or step-down transformer, the different supply frequencies mean that motors will run at the wrong speed and quickly burn out. The larger and more powerful the motor is, the more this is true. Don't, for example, bring a vacuum cleaner from the US to Europe (or vice versa). It's almost guaranteed to fail--even if you have a voltage converter.

Electric shavers[edit]

Hotels often provide a special electrical outlet specifically for electric shavers. They allow any voltage shaver to be plugged into them and be used safely in front of the bathroom mirror. They may also accept your cellphone adaptor or similar low power battery charging unit. Many--but not all-- electric shavers sold today are dual voltage 50/60Hz and some will even recharge the battery at 12V DC (such as in an automobile). Check the label and instructions for compatibility.

Hairdryers[edit]

Hairdryers are a particular risk; if you accidentally plug your 100-120V hairdryer into a 240V outlet. you may find it catching fire in your hands! Newer models should have a thermal switch, though. Allow 15-20 mins for it to cool down, then use a voltage converter (if the dryer is 50 Hz compatible). Similarly, a 220-240V hairdryer in a 120V outlet may run slowly and not heat up enough. Most good hotels and motels will be able to supply a hairdryer, and it may even be a room fitting. However, it may be worthwhile buying or borrowing a hairdryer suited for the electrical system of countries you'll be traveling in.
Many new hairdryers sold in 100-120V countries are dual voltage with settings for 100-120V and 220-240V. Even though it's motorized, it will work on either 50 or 60 Hz. Don't forget to lockout the high setting with a flat screwdriver or something similar. At 220-240V, the low setting becomes as powerful as the high setting was at home (with 'low' unavailable).

Clocks[edit]

An electric clock of any sort is sensitive to voltage. If the voltage is doubled or halved, it will not function and may burn out. Furthermore, the electric frequency (50 or 60 Hz) is used in cheap clocks (such as many clock-radio style clocks) to keep the time. Thus, if a clock made for North America were used in Europe – even with a voltage adapter – it would lose 10 min/h! Obviously, not a great idea if you have a train to catch. On the other hand, if the clock has a quartz crystal, this is used for the timekeeping, and it operates independently of the line frequency. Inexpensive, battery-operated, digital LCD travel clocks (with a push button back light) are also available. These are recommended for destinations with frequent blackouts.

Video equipment[edit]

Televisions, many radios, video and DVD players, as well as videotapes, are often specific to the broadcast system used in the country that they are sold in, usually associated with the frequency of the country's electric current. For example, North America is 60 Hz and its television is 30 frames per second, while Europe is 50 Hz and its television is 25 frames per second. The main three analogue television broadcast systems are PAL, the closest to a worldwide standard, NTSC, used mostly in the Americas and some East Asian countries (notably JapanSouth Korea, and Taiwan) and SECAM, originally from Franceand adopted by much of Eastern Europe and the Middle East, but there are various incompatibilities even within these supposed standards. There is no difference between PAL and SECAM for unconverted DIGITAL video including DVDs. However, any analog output to a television set would be in the native format of the country of location. Brazil uses a hybrid PAL/NTSC standard called "PAL-M". In Brazil, DVDs and video tape are the same as NTSC (without region coding- see below), but all players and TV sets are useless outside the country unless they have a separate NTSC setting.
Before purchasing any video equipment, read the manual and warranty carefully. For TVs and VCRs, don't forget about cable television frequencies; they may not be the same, even if everything else is. Television sets often won't work correctly in another country from where they were sold, even if the voltage and video standard are the same. For example, a television set made for the USA will skip a few channels in Japan. Furthermore, many countries have or are in the process of switching to digital over-the-air broadcasting, (dates by country). Unless you have an internationally compatible device, you may find your expensive looking system is little more than worthless junk in another country because it won't work with your country's broadcast system. Your warranty is probably only valid in the country of purchase, and you may need to return the goods to the place you purchased them from.
The final problem with transporting TVs is that many European countries, notoriously the UK, require a license to watch any live TV (over-the-air, cable, satellite, and even live-streams on the internet). Fines can be hefty (in addition to being charged for the license).
DVD and Blu-Ray, infuriatingly, have completely artificial limitations introduced in the form of region coding, which attempts to limit the region where the discs can be used, as a technique to keep the various regions as separate markets. For example, a Region 1 player for North America will not play a Region 3 DVD for Hong Kong. The workarounds are to obtain either a regionless DVD player which ignores the code, purchase multi-region discs (Regions 1 and 3 in this case), or better yet, Region 0 discs, which can be played on any device. Blu-Ray discs cannot be played at all in a standard DVD player -- not even at a lower resolution. However, Blu-Ray discs played on a Blu-Ray player can be displayed on a standard def. television, provided you have the correct cables and connections. (HDMI cables are not compatible.)
Technically, there is no such thing as an NTSC or PAL DVD disc, as all color information is the same for both. When discs are labelled as such, what they're referring to is the picture size and frame rate (i.e. number of frames per second) that are used in most (but not all!) countries that have TV broadcasts on this same system. Many NTSC players cannot play PAL DVDs, unless that's a specific feature included (many Philips and JVC models include this). PAL DVD players are generally much better at playing NTSC, but it's not a certainty. If all else fails, a computer DVD-ROM can play any DVD movie, though there's a limit on how many times you can change the region code. Unlike analogue television sets, computer monitors can automatically handle both 25 (PAL and SECAM) and 30 (NTSC) frames per second, as well as various picture sizes. This also applies to LCD and plasma "flat panel" television sets, but don't expect their tuner to be compatible outside the country in which they were sold.
Video cameras can usually be charged with both electrical systems so you can record during travels and view it back home. Digital cameras and video cameras can usually output to both PALNTSC, and SECAM, so you can view your recording while travelling. Bring an RCA (yellow plug) to SCART adaptor if you plan to view video from a camcorder on a European television set.
If you have something on VHS video tape, it's best to convert to DVD before traveling. (Conversions between PAL and NTSC can be done before burning.) Use a video capture card for recording the VHS into a digital file on your computer. Then with DVD-making software, burn the file to a blank DVD.
Note that to be playable on a television set using a connected DVD player, a burned disc must be in the native DVD format (same as Hollywood movies) with the "AUDIO_TS" and "VIDEO_TS" folders. If you burn a Windows media, Powerpoint, Quicktime, Adobe flash, etc. file to a DVD, it can only be played back on another computer. This may be totally inadequate for a presentation. Unless your company or organization is already equipped, locating a computer video projector in a foreign country can be a challenge. Traveling with one is not recommended either, as they are expensive, fragile, and somewhat bulky and heavy. Exception: many newer DVD players can play "JPG" still picture files as a slideshow. Some even have an SD card slot, so you can view your photos taken from a digital camera. Caution: NEVER computer-edit anything directly on a photo-media card (SD, CF, Sony memory stick, etc.) Copy it to the hard drive or a USB jump drive first, then edit.
If required, converting DVDs from one format to another (PAL, NTSC), can be done on a computer with a fast CPU, or you can get it done professionally. Allow plenty of time, as this can take many hours. Regular blank discs work fine for making copies of a foreign format, as it's all just a bunch of ones and zeros and no different than copying anything else. Copies can be made quickly, while conversions cannot.

Stay safe[edit]

The electrical engineer's maxim: The smoke that escapes from a device or a component is its spirit without which it cannot work. In other words: if smoke rises from the device, then it's destroyed.
The first time you use electrical equipment on a voltage system you haven't used before, watch for excessive heat, strange smells, and smoke. This is especially true for those residing in countries with 120V (USA, Canada, Japan, etc.) visiting places with the higher voltage. Smoke is a sure sign your equipment cannot cope with the voltage system.
If your electrical equipment gets very hot, smells of burning (there is a distinct smell of electrically fried circuit boards) or starts to smoke, turn it off at the wall or the main switch immediately, then carefully unplug the equipment. Do not disconnect or unplug by just grabbing the smoking device, its plug or cord, and then unplugging it, as these parts are probably very hot, and the insulation could be melted or unsafe, which could result in electrocution.
You may find your expensive equipment has been fried and needs to be replaced because the wrong voltage was used. However, if the equipment only got hot and did not smoke or produce strange burning smells you may be lucky. Some older devices have fuses that you may be able to replace. New devices, such as gaming consoles, will trip a circuit breaker. Disconnect them from all power and leave them for 60 minutes or so, and the circuit breaker will normally reset.
Do not rely on fuses to protect your equipment. If a fuse does blow, you should have things checked by an electrician before using the suspect equipment again.
In Third World countries with frequent blackouts, it's not at all uncommon for a visitor to plug something in and have the power go out coincidentally. Always check the neighborhood first, before blaming the appliance or looking at the fuse/circuit breaker.

Graphene


Graphene, the well-publicised and now famous two-dimensional carbon allotrope, is as versatile a material as any discovered on Earth. Its amazing properties as the lightest and strongest material, compared with its ability to conduct heat and electricity better than anything else, mean that it can be integrated into a huge number of applications. Initially this will mean that graphene is used to help improve the performance and efficiency of current materials and substances, but in the future it will also be developed in conjunction with other two-dimensional (2D) crystals to create some even more amazing compounds to suit an even wider range of applications. To understand the potential applications of graphene, you must first gain an understanding of the basic properties of the material.
The first time graphene was artificially produced; scientists literally took a piece of graphite and dissected it layer by layer until only 1 single layer remained. This process is known as mechanical exfoliation. This resulting monolayer of graphite (known as graphene) is only 1 atom thick and is therefore the thinnest material possible to be created without becoming unstable when being open to the elements (temperature, air, etc.). Because graphene is only 1 atom thick, it is possible to create other materials by interjecting the graphene layers with other compounds (for example, one layer of graphene, one layer of another compound, followed by another layer of graphene, and so on), effectively using graphene as atomic scaffolding from which other materials are engineered. These newly created compounds could also be superlative materials, just like graphene, but with potentially even more applications.
After the development of graphene and the discovery of its exceptional properties, not surprisingly interest in other two-dimensional crystals increased substantially. These other 2D crystals (such as Boron Nitride, Niobium Diselenide and Tantalum (IV) sulphide), can be used in combination with other 2D crystals for an almost limitless number of applications. So, as an example, if you take the compound Magnesium Diboride (MgB2), which is known as being a relatively efficient superconductor, then intersperse its alternating boron and magnesium atomic layers with individual layers of graphene, it improves its efficiency as a superconductor. Or, another example would be in the case of combining the mineral Molybdenite (MoS2), which can be used as a semiconductor, with graphene layers (graphene being a fantastic conductor of electricity) when creating NAND flash memory, to develop flash memory to be much smaller and more flexible than current technology, (as has been proven by a team of researchers at the École Polytechnique Fédérale de Lausanne (EPFL) in Switzerland).
The only problem with graphene is that high-quality graphene is a great conductor that does not have a band gap (it can’t be switched off). Therefore to use graphene in the creation of future nano-electronic devices, a band gap will need to be engineered into it, which will, in turn, reduce its electron mobility to that of levels currently seen in strained silicon films. This essentially means that future research and development needs to be carried out in order for graphene to replace silicon in electrical systems in the future. However, recently a few research teams have shown that not only is this possible, it is probable, and we are looking at months, rather than years, until this is achieved at least at a basic level. Some say that these kinds of studies should be avoided, though, as it is akin to changing graphene to be something it is not.
In any case, these two examples are just the tip of the iceberg in only one field of research, whereas graphene is a material that can be utilized in numerous disciplines including, but not limited to: bioengineering, composite materials, energy technology and nanotechnology.
Biological Engineering
Bioengineering will certainly be a field in which graphene will become a vital part of in the future; though some obstacles need to be overcome before it can be used. Current estimations suggest that it will not be until 2030 when we will begin to see graphene widely used in biological applications as we still need to understand its biocompatibility (and it must undergo numerous safety, clinical and regulatory trials which, simply put, will take a very long time). However, the properties that it displays suggest that it could revolutionise this area in a number of ways. With graphene offering a large surface area, high electrical conductivity, thinness and strength, it would make a good candidate for the development of fast and efficient bioelectric sensory devices, with the ability to monitor such things as glucose levels, haemoglobin levels, cholesterol and even DNA sequencing. Eventually we may even see engineered ‘toxic’ graphene that is able to be used as an antibiotic or even anticancer treatment. Also, due to its molecular make-up and potential biocompatibility, it could be utilised in the process of tissue regeneration.
Optical Electronics
One particular area in which we will soon begin to see graphene used on a commercial scale is that in optoelectronics; specifically touchscreens, liquid crystal displays (LCD) and organic light emitting diodes (OLEDs). For a material to be able to be used in optoelectronic applications, it must be able to transmit more than 90% of light and also offer electrical conductive properties exceeding 1 x 106 Ω1m1 and therefore low electrical resistance. Graphene is an almost completely transparent material and is able to optically transmit up to 97.7% of light. It is also highly conductive, as we have previously mentioned and so it would work very well in optoelectronic applications such as LCD touchscreens for smartphones, tablet and desktop computers and televisions.
Currently the most widely used material is indium tin oxide (ITO), and the development of manufacture of ITO over the last few decades time has resulted in a material that is able to perform very well in this application. However, recent tests have shown that graphene is potentially able to match the properties of ITO, even in current (relatively under-developed) states. Also, it has recently been shown that the optical absorption of graphene can be changed by adjusting the Fermi level. While this does not sound like much of an improvement over ITO, graphene displays additional properties which can enable very clever technology to be developed in optoelectronics by replacing the ITO with graphene. The fact that high quality graphene has a very high tensile strength, and is flexible (with a bending radius of less than the required 5-10mm for rollable e-paper), makes it almost inevitable that it will soon become utilized in these aforementioned applications.
In terms of potential real-world electronic applications we can eventually expect to see such devices as graphene based e-paper with the ability to display interactive and updatable information and flexible electronic devices including portable computers and televisions.
Ultrafiltration
Another standout property of graphene is that while it allows water to pass through it, it is almost completely impervious to liquids and gases (even relatively small helium molecules). This means that graphene could be used as an ultrafiltration medium to act as a barrier between two substances. The benefit of using graphene is that it is only 1 single atom thick and can also be developed as a barrier that electronically measures strain and pressures between the 2 substances (amongst many other variables). A team of researchers at Columbia University have managed to create monolayer graphene filters with pore sizes as small as 5nm (currently, advanced nanoporous membranes have pore sizes of 30-40nm). While these pore sizes are extremely small, as graphene is so thin, pressure during ultrafiltration is reduced. Co-currently, graphene is much stronger and less brittle than aluminium oxide (currently used in sub-100nm filtration applications). What does this mean? Well, it could mean that graphene is developed to be used in water filtration systems, desalination systems and efficient and economically more viable biofuel creation.
Composite Materials
Graphene is strong, stiff and very light. Currently, aerospace engineers are incorporating carbon fibre into the production of aircraft as it is also very strong and light. However, graphene is much stronger whilst being also much lighter. Ultimately it is expected that graphene is utilized (probably integrated into plastics such as epoxy) to create a material that can replace steel in the structure of aircraft, improving fuel efficiency, range and reducing weight. Due to its electrical conductivity, it could even be used to coat aircraft surface material to prevent electrical damage resulting from lightning strikes. In this example, the same graphene coating could also be used to measure strain rate, notifying the pilot of any changes in the stress levels that the aircraft wings are under. These characteristics can also help in the development of high strength requirement applications such as body armour for military personnel and vehicles.
Photovoltaic Cells
Offering very low levels of light absorption (at around 2.7% of white light) whilst also offering high electron mobility means that graphene can be used as an alternative to silicon or ITO in the manufacture of photovoltaic cells. Silicon is currently widely used in the production of photovoltaic cells, but while silicon cells are very expensive to produce, graphene based cells are potentially much less so. When materials such as silicon turn light into electricity it produces a photon for every electron produced, meaning that a lot of potential energy is lost as heat. Recently published research has proved that when graphene absorbs a photon, it actually generates multiple electrons. Also, while silicon is able to generate electricity from certain wavelength bands of light, graphene is able to work on all wavelengths, meaning that graphene has the potential to be as efficient as, if not more efficient than silicon, ITO or (also widely used) gallium arsenide. Being flexible and thin means that graphene based photovoltaic cells could be used in clothing; to help recharge your mobile phone, or even used as retro-fitted photovoltaic window screens or curtains to help power your home.
Energy Storage
One area of research that is being very highly studied is energy storage. While all areas of electronics have been advancing over a very fast rate over the last few decades (in reference to Moore’s law which states that the number of transistors used in electronic circuitry will double every 2 years), the problem has always been storing the energy in batteries and capacitors when it is not being used. These energy storage solutions have been developing at a much slower rate. The problem is this: a battery can potentially hold a lot of energy, but it can take a long time to charge, a capacitor, on the other hand, can be charged very quickly, but can’t hold that much energy (comparatively speaking). The solution is to develop energy storage components such as either a supercapacitor or a battery that is able to provide both of these positive characteristics without compromise.
Currently, scientists are working on enhancing the capabilities of lithium ion batteries (by incorporating graphene as an anode) to offer much higher storage capacities with much better longevity and charge rate. Also, graphene is being studied and developed to be used in the manufacture of supercapacitors which are able to be charged very quickly, yet also be able to store a large amount of electricity. Graphene based micro-supercapacitors will likely be developed for use in low energy applications such as smart phones and portable computing devices and could potentially be commercially available within the next 5-10 years. Graphene-enhanced lithium ion batteries could be used in much higher energy usage applications such as electrically powered vehicles, or they can be used as lithium ion batteries are now, in smartphones, laptops and tablet PCs but at significantly lower levels of size and weight.
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Thursday, March 31, 2016

Is your doctor on probation?

Look him / her up.

Honda's New Hydrogen-Powered Vehicle


UPDATE: This story was updated to add the car’s official name, Honda Clarity, which was announced at a press conference Wednesday. 
TOKYO — The most notable thing about Honda Motor's ‘s new hydrogen-powered Clarity fuel cell vehicle, unveiled Wednesday at the Tokyo Motor Show, is not the silent burst of acceleration it provides when your foot touches the pedal, or the fact that it emits nothing but water vapor from the tailpipe. It’s not even that the Clarity can go more than 400 miles between three-minute hydrogen fillings - assuming you have access to a hydrogen station.
No, the most important thing is that Honda’s new fuel cell system is one-tenth the cost of previous versions and — for the first time — fits neatly under the car’s hood, taking up no more space than a typical V-6 engine. That means two things: 1) there’s more space for passengers and cargo, and 2) the compact fuel cell power train can be used in a variety of other Honda vehicles.
This really does feel like a real leap forward in the shift toward fuel cell vehicles and a so-called “hydrogen society.”
Of course, getting the hydrogen remains a sticking point. In California and the Northeast, companies like First Element and Air Liquide are installing hydrogen stations with support from government grants as well as loans from Toyota and Honda, but the rollout to date has been slow.
Honda might have a solution, though: it’s developing a compact Smart Hydrogen Station, enabling you to use high-pressure electrolysis to produce your own hydrogen at home. There’s no word on when that might be available, but if it’s affordable, it could be a huge breakthrough in speeding the adoption of fuel cell vehicles.
The Clarity goes on sale next spring (about six months behind Toyota Motor's ‘s recently introduced Mirai fuel cell) and the automaker expects to sell far more than the 72 units sold of its previous-generation fuel cell, the FCX Clarity. Honda said the same platform will also underpin a new plug-in hybrid vehicle, coming shortly after the fuel cell vehicle’s launch. Honda said it sees plug-in hybrids as an important bridge toward hydrogen-powered fuel cells.

Image result for hydrogen powered car pic
UPDATE: This story was updated to add the car’s official name, Honda Clarity, which was announced at a press conference Wednesday. 
TOKYO — The most notable thing about Honda Motor's ‘s new hydrogen-powered Clarity fuel cell vehicle, unveiled Wednesday at the Tokyo Motor Show, is not the silent burst of acceleration it provides when your foot touches the pedal, or the fact that it emits nothing but water vapor from the tailpipe. It’s not even that the Clarity can go more than 400 miles between three-minute hydrogen fillings - assuming you have access to a hydrogen station.
No, the most important thing is that Honda’s new fuel cell system is one-tenth the cost of previous versions and — for the first time — fits neatly under the car’s hood, taking up no more space than a typical V-6 engine. That means two things: 1) there’s more space for passengers and cargo, and 2) the compact fuel cell power train can be used in a variety of other Honda vehicles.
This really does feel like a real leap forward in the shift toward fuel cell vehicles and a so-called “hydrogen society.”
Of course, getting the hydrogen remains a sticking point. In California and the Northeast, companies like First Element and Air Liquide are installing hydrogen stations with support from government grants as well as loans from Toyota and Honda, but the rollout to date has been slow.
Honda might have a solution, though: it’s developing a compact Smart Hydrogen Station, enabling you to use high-pressure electrolysis to produce your own hydrogen at home. There’s no word on when that might be available, but if it’s affordable, it could be a huge breakthrough in speeding the adoption of fuel cell vehicles.
The Clarity goes on sale next spring (about six months behind Toyota Motor's ‘s recently introduced Mirai fuel cell) and the automaker expects to sell far more than the 72 units sold of its previous-generation fuel cell, the FCX Clarity. Honda said the same platform will also underpin a new plug-in hybrid vehicle, coming shortly after the fuel cell vehicle’s launch. Honda said it sees plug-in hybrids as an important bridge toward hydrogen-powered fuel cells.

Despite its compact size, the new fuel cell system gets a 30 percent increase in power, to 130 kilowatts, with a 700-kilometer (435 mile) range. It’s paired with a flat lithium-ion battery pack that fits under the front seats. There are two hydrogen tanks: a large one that fits behind the rear bulkhead, with a smaller one under the rear seat. The larger tank clearly cuts into trunk space, but there’s still a decent amount of room for golf bags or luggage.
Virtually every automaker is working on fuel cell vehicles; it’ll be interesting to see how they develop. Just as with hybrid vehicles a generation ago, it’s Honda and Toyota leading the way.

Cricket Explained

Cricket is a ball game played by two teams with 11 players on each side. In a way, cricket is similar to baseball – one man throws a ball at the batsman who tries to hit it as far as possible while other players in the field try to catch the ball or stop it from going out of the field, and prevent the batsman from scoring runs. However, it is more elaborate and of longer duration than its American counterpart. Various versions of the game have evolved over the years. I will attempt to explain the game as simply as possible so as to enable the uninitiated to strike a conversation on cricket.
Cricket is a religion in India. No other sport generates such mass hysteria and madness in the country. It unites strangers and makes friends out of enemies. Streets empty out whenever India plays against a formidable opponent, especially Pakistan. It is no wonder that cricket is considered the unofficial national game of India (the official national game being field hockey).
The roots of cricket date back to the 16th century. However, the modern version of the game dates back to 1844. Today, most Commonwealth nations play professional cricket.
I will take you through the game by explaining the rules, the various formats of the game, key nations and the best international players. I hope you will enjoy this series and pick up enough knowledge to talk your way through a casual conversation on the game.
As explained above, cricket is by far the most popular sport in India and has evolved over the years: first there was only the five-day game, then came the one-day game and today there is also a three-hour game (known as “20:20”). All the formats are still in vogue in India and various tournaments are held in each format – both national and international.
Cricket is played in open fields or stadiums on a “pitch” – a rectangular ground 20.12m (22 yards) long and 3.05m wide.
It is bound at either end by the “bowling creases” and on each end are the “wickets” which are three sticks or “stumps” with two “bails” balanced on top. The aim of the batsmen is to defend the wickets and make as many “runs” between the wickets as possible; while the bowler aims to get the batsmen “out” by hitting the wicket and knocking the wooden bails balanced on top. On getting out, the batsman has to return to the pavilion and the next batsman replaces him. There are other ways of getting the batsman out: through a “catch” where a fielder or the “wicket-keeper” catches the ball while it is still in the air after being hit by the batsman, being “run-out” where the batsmen “runs” after hitting the ball (similar to baseball) and is not able to reach the “return crease” before a fielder (or the bowler), hits the wicket at either end with the ball, “LBW” (Leg Before Wicket) where the ball hits the batsman’s leg, which is blocking the wicket, “Stumped” where the wicket-keeper knocks the bails off the stumps after catching a ball that passes by the batsman without touching either the bat or the wicket while the batsman is still outside the “batting crease”, “Hit-wicket” where the batsman accidentally hits the wickets with his bat or accidentally trips and falls on the wickets.
There are two key scores in cricket; the number of runs that have been made; and the number of batsmen that have got out. The batsmen tries to get as many “runs” as possible for his team while the other team bowls. Runs can be scored by running between the wickets after hitting the ball or by hitting the ball hard enough to make it go out of the ground either touching the ground (4 runs, also known as a “boundary”) or flying out without touching the ground (6 runs, called a Sixer). The higher scoring team wins the match.
Now, we’ll talk of the oldest and the longest version of the game – the five day format popularly known as “Test Cricket”. Test Cricket usually lasts for five days with each team batting and bowling twice; at the end of which, the game can still end in a “draw” with no team winning!
Test cricket is played in “innings” during which one team attempts to score while the other team attempts to prevent the first from scoring. The competing teams alternate who is “in bat” and who is bowling. The exception to this rule is a “follow-on”. This happens if, at the end of its first innings, Team B’s total falls short of Team A’s first innings’ total by at least 200 runs, the captain of Team A can choose to order Team B to stay in bat. If he does so, Team B must commence its second batting innings immediately (i.e. following on from their last batting). Each innings lasts until all the batsmen are dismissed or until the batting team “declares” the innings over after having established a big “score” of runs.
After having explained about Test Cricket, I will explain about the faster and shorter format of the game – the One Day International Cricket (ODI). In an ODI, 50 “overs” (a set of six consecutive balls bowled in succession) are played per side between two national cricket teams.
The basic rules of cricket are followed. The Captain of the team winning the “toss” chooses to either “bat” or “bowl” (field) first. The team batting first sets the target score in 50 overs.
The innings lasts until the batting side is “all out” (i.e., 10 of the 11 batting players are “out”) or all of the first side’s allotted overs are used up. The team batting second tries to score more than the target score in order to win the match. Similarly, the side bowling second tries to bowl out the second team for less than the target score in order to win. The game is declared as a “tie” (regardless of the number of wickets lost by either team) if the number of runs scored by both teams are equal, when the second team loses all of its “wickets” (batsmen getting out) or exhausts all its overs.
ODIs were introduced in the 1970s and gained popularity because the game gets over within about 8 hours and is always action packed unlike a Test Match which can get boring at times. It is also played as a “day – night” game with one innings being played during the day and the other stretching into the night and being played in flood lights.
The popularity of One Day International Cricket (ODI) cricket  soared through the late 1980s & 1990s and peaked in the last decade. However, the latest version of the game –  Twenty20 or T20 is already beginning to dwarf the popularity of the ODIs.
The rules of cricket remain the same. The major difference is that instead of 50 overs per inning, there are only 20 overs per inning. The popularity of the game lies in its short playing hours – 75 minutes for each side. In about three hours, the result is out. This keeps the tempo of the game throughout in top gear. Formally introduced in 2003, T20 has come a long way with even a World Cup of its own.
Though India made its International T20 debut only as recently as in 2006, the game has already broken all records of popularity with the introduction of the Indian Premier League (on the lines of the English Premier League) which has taken the game to the next level of entertainment.

Erica, the 'most beautiful and intelligent' android.

*Too weird and believe I can say where this is going.

Erica enjoys the theatre and animated films, would like to visit south-east Asia, and believes her ideal partner is a man with whom she can chat easily.
She is less forthcoming, however, when asked her age. “That’s a slightly rude question … I’d rather not say,” comes the answer. As her embarrassed questioner shifts sideways and struggles to put the conversation on a friendlier footing, Erica turns her head, her eyes following his every move.
It is all rather disconcerting, but if Japan’s new generation of intelligent robots are ever going to rival humans as conversation partners, perhaps that is as it should be.
Erica, who, it turns out, is 23, is the most advanced humanoid to have come out of a collaborative effort between Osaka and Kyoto universities, and the Advanced Telecommunications Research Institute International (ATR).
At its heart is the group’s leader, Hiroshi Ishiguro, a professor at Osaka University’s Intelligent Robotics Laboratory, perhaps best known for creating Geminoid HI-1, an android in his likeness, right down to his trademark black leather jacket and a Beatles mop-top made with his own hair.
Geminoid HI-1 - a humanoid made in Ishiguro’s likeness - and Geminoid F, the world’s first humanoid actor.
Erica, however, looks and sounds far more realistic than Ishiguro’s silicone doppelganger, or his previous human-like robot, Geminoid F. Though she is unable to walk independently, she possesses improved speech and an ability to understand and respond to questions, her every utterance accompanied by uncannily humanlike changes in her facial expression.
Erica, Ishiguro insists, is the “most beautiful and intelligent” android in the world. “The principle of beauty is captured in the average face, so I used images of 30 beautiful women, mixed up their features and used the average for each to design the nose, eyes, and so on,” he says, pacing up and down his office at ATR’s robotics laboratory. “That means she should appeal to everyone.”
She is a more advanced version of Geminoid F, another Ishiguro creation which this year appeared in Sayonara, director Koji Fukada’s cinematic adaptation of a stage production of the same name.
The movie, set in rural Japan in the aftermath of a nuclear disaster, made Geminoid F the world’s first humanoid film actor, co-starring opposite Bryerly Long. While robots in films are almost as old as cinema itself, Erica did not rely on human actors – think C-3PO – or the motion-capture technology behind, for example, Sonny from I, Robot.
Although the day when every household has its own Erica is some way off, the Japanese have demonstrated a formidable acceptance of robots in their everyday lives over the past year.
From April, two branches of Mitsubishi UFJ Financial Group started employing androids to deal with customer enquiries. Pepper, a humanoid home robot, went on sale to individual consumers in June, with each shipment selling out in under a minute.
This year also saw the return to Earth of Kirobo, a companion robot, from a stay on the International Space Station, during which it became the first robot to hold a conversation with a human in space.
And this summer, a hotel staffed almost entirely by robots – including the receptionists, concierges and cloakroom staff – opened at the Huis Ten Bosch theme park near Nagasaki, albeit with human colleagues on hand to deal with any teething problems.
Sonny from I, Robot.
But increasing daily interaction with robots has also thrown up ethical questions that have yet to be satisfactorily answered. SoftBank, the company behind Pepper, saw fit to include a clause in its user agreement stating that owners must not perform sexual acts or engage in “other indecent behaviour” with the android.
Ishiguro believes warnings of a dystopian future in which robots are exploited – or themselves become theabusers – are premature. “I don’t think there’s an ethical problem,” he says. “First we have to accept that robots are a part of our society and then develop a market for them. If we don’t manage to do that, then there will be no point in having a conversation about ethics.”
Nomura Research Institute offered a glimpse into the future with a recent report in which it predicted that nearly half of all jobs in Japan could be performed by robots by 2035.
“I think Nomura is on to something,” says Ishiguro. “The Japanese population is expected to fall dramatically over the coming decades, yet people will still expect to enjoy the same standard of living.” That, he believes, is where robots can step in.
In Erica, he senses an opportunity to challenge the common perception of robots as irrevocably alien. As a two-week experiment with android shop assistants at an Osaka department store suggested, people may soon come to trust them more than they do human beings.

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