Digital Camera Information

Could the future of camera chips be based on light? Scientist has discovered that light can be slowed down so that a beam of sunlight can travel at a leisurely stroll and be brought to a standstill, or even stored for later use in the form of a rainbow.

The details of an exotic kind of material that can slow light from its top speed of around one million million metres per hour so that it can be trapped as a crescent of colour is published by a team that suggests if could mark a revolution in computing.

This remarkable feat could allow “broadband storage” for “broadband computing” capable of much greater power than conventional silicon chips because it can process information in the form of many light beams simultaneously, just as optical fibres can carry lots of conversations simultaneously. And it could also mark an advance in quantum computing, named after the strange quantum properties of matter at the atomic level, that could enhance the power of computers millions of times beyond anything available today.

The extraordinary feat of optical sorcery is described today in the journal Nature by Professor Ortwin Hess and Kosmas Tsakmakidis at the University of Surrey, working with Professor Alan Boardman from Salford University.

Once theory is turned into reality, the technique will allow the use of light rather than electrons to store memory in devices such as computers and cameras. The team predicts an increase in operating capacity of 1,000% over the use of conventional electronics by exploiting light’s broad spectrum to lay down lots of different information simultaneously in the first “optical capacitor.”

Slow light could also, paradoxically, be used to increase the speed of optical networks, such as the Internet. At major interconnection points, where billions of parcels of information from myriad phone calls arrive simultaneously, these materials could be used to slow, divert and allow through information, working in the same way as traffic congestion calming schemes do on motorways, when a reduction in the speed limit can lead to a swifter overall flow of traffic.

Previous attempts to slow and capture light have until now required extremely low temperatures, have been extremely costly, and have only worked with one specific frequency of light at a time. The new technique proposed by Prof Hess and Kosmas Tsakmakidis involves the use of exotic “metamaterials” with extraordinary optical properties.

These materials, which consist of carefully-designed shards of metal a billionth of a metre across (nanometres), have the strange property of negative refraction, which means that light bends in the opposite direction to the way it shifts when passing from one ordinary material into another (think of how a straight stick in water looks bent.) This means that, in theory at least, a metamaterial could be designed so that light would curve around it, making the object invisible, an idea already under serious study for cloaking devices. When combined with the “Goos Hänchen effect,” where light can even go backwards, Prof Hess’s team has shown it is possible to use metamaterials to halt a light beam in its tracks.

As different component ‘colours’ of white light have different frequencies (colours) each individual frequency be stopped at a different stage of a wedge of such material, he said, likening the way the light slows down to walking on shingle. At the point that every step of the light beam forward leads to an equivalent slip backwards in the metamaterial, an effect that depends on the colour of the light.

The result is a ‘trapped rainbow’. “The key to understanding the trapping of the rainbow,” he says, “is that every frequency of a white light wave packet has in a tapered shape of metamaterial its own particular width where it eventually stops – the result is the spatial spread of stopped/trapped light – the trapped rainbow.” Prof Hess said that an onlooker could in an appropriate arrangement of metamaterial layers (as shown here) see the rainbow of trapped light.

This ability to store light will conceivably provide a powerful new tool to control optical information, even harness the quantum properties of atoms, and so exploit the possibilities of quantum computers that, in theory, will be able solve problems millions of times faster than current machines.

The extraordinary properties of quantum computers were first explored by theorists such as the late Richard Feynman at Caltech and David Deutsch of Oxford University. While a conventional PC shuffles information in the form of binary numbers, those containing only the digits 1 and 0, which it remembers as the “on” and “off” positions of tiny switches, or “bits.”

By contrast, the switches in a quantum computer can be both “on” and “off” at the same time. A “qubit” could do two calculations at once, two qubits would do four and so on. Thus, it was theoretically possible to use quantum computers to explore vast numbers of potential solutions to a problem simultaneously. The new work, which suggests a way to create optical qubits, adds to a range of recent advances that make scientists confident that quantum computers will be feasible within a few years.

An artist’s impression depicting how the trapped rainbow is displayed below.

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Fuel cells used in electronic products will soon become a reality in 2008.

Just recently, Sweden based Morphic Technologies’ subsidiary Cell Impact AB has received a further order relating to initial mass production of fuel cell flow plates for operating consumer electronics from Asia.

The Asian purchaser is one of the world’s largest electronics manufacturers. The initial order is valued at around MSEK 90 and the first delivery is to take place 2nd quarter 2008.

Cell Impact has received a further order relating to the production of flow plates for methanol fuel cells. The purchaser this time is a global electronics manufacturer which has been evaluating Cell Impact flow plates for some time. The plates are to be used in a number of the customer’s future products, powered by fuel cells.

Second order in a short time
The order is the second volume order within a short period. At the end of August, Cell Impact received its first volume order concerning series production of fuel cell plates for operating consumer electronics for a customer in the USA. That contract has a value of approx. MSEK 60 over a two-year period. As has already been communicated, apart from the now published orders, Cell Impact has also received a number of test orders for flow plates from players within various areas of application, including the vehicle industry.

Production of the flow plates will take place, in both cases, at the Cell Impact production facility in Karlskoga.

“The fact that one of the world’s biggest players within consumer electronics is choosing us as it´s supplier shows the strength of what we have to offer. However, this order is not just a breakthrough for us, it is also a breakthrough for the entire fuel cell industry”, says Jonas Eklind, President and CEO at Morphic Technologies.

“We have now reached the point where fuel cells are in the consumer field. The fact that this order also relates to fuel cells for consumer electronics is characteristic of the way things are developing within the fuel cell field right now. In all certainty, consumer electronics, including computers, cameras and MP3 players, are going to be the first area in which we will see products powered by fuel cells. We estimate that methanol fuel cells for consumer electronics will start being introduced onto the market in 2008“, says Martin Valfridsson, MD at Cell Impact.

The principal advantages of fuel cells in consumer electronics include their significantly longer operating times. Unlike today’s batteries, very rapid charging of discharged units powered by fuel cells will also be possible.

In a fuel cell system for consumer electronics, electricity is produced by breaking down the fuel which then reacts with oxygen. Fuel cell technology has a great potential because of its virtually non-existent impact on the environment and its superior level of efficiency.

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It looks like Canon will be continuing to invest heavily on building another CMOS sensor plant expanding on the growth of digital camera. By expanding in another plant, it helps to reduce costs whilst increasing profits.

Here’s what ruters has to say:

“TOKYO (Reuters) - Canon Inc. (7751.T: Quote, Profile, Research) will invest about 55 billion yen ($451 million) to build a new factory in Japan to double its production capacity of image sensors used in digital cameras.

Canon is aiming to produce 24 million digital cameras this year, including 3 million SLRs, which are high-end models that use interchangeable lenses.”

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Could this be the next thing for digital cameras, a fuel cell? According to FuelCellToday, they say Samsung Electro-Mechanics has already developed a micro fuel cell and hydrogen generator that runs on water. Yes, that right water, H-2-0!

According to the Chosen Ilbo, mobile phones or even Digital Cameras which run on water could hit the market as soon as 2010 as a result of this development.

The micro fuel cell can be used to power mobile devices as it can generate up to three watts of electricity, Samsung has said, according to Chosen Ilbo.

This means that the fuel cell could power a handset for up to ten hours.

Explaining the process, Oh Yong-soo, vice president of Samsung Electro-Mechanics’ research centre, told Chosen Ilbo: “When the handset is turned on, metal and water in the phone react to produce hydrogen gas.

“The gas is then supplied to the fuel cell where it reacts with oxygen in the air to generate power.”

Cartridges would have to be changed once every five days based on usage of around four hours a day on average, the vice president added.

Samsung already has a fuel cell in their laptops (Sense Q35) that could run for up to 30 days and is due at the end of 2007.

It looks like Sony is investing heavily in its sensor production facility in Japan. According to the press release, Sony Corporation announced that it would invest approximately 60 billion JPY in Sony Semiconductor Kyushu Corporation’s Kumamoto Technology Centre (Kumamoto TEC) Fab 2 facility, to extend clean room facilities by 5,000m² and reinforce image sensor fabrication capacity. This investment will take place from fiscal year 2007 to fiscal 2009.

Sony is positioning image sensors as a key focus area of its semiconductor business. Through the reinforcement of this facility, Sony will strengthen supply and provide the platform for further image sensor business growth.

Kumamoto TEC has continued to expand its operations as Sony’s principle facility for the fabrication of imaging devices, such as the CCDs, CMOS sensors and micro-display devices that are Sony’s strengths. In particular, demand for CMOS sensors has demonstrated rapid growth in recent years. In view of this, Sony is enhancing production operations for this market, with mass production having already commenced at Fab 2’s existing 5,000m² production facility in Spring t

Over the next three years, Sony will continue to strengthen its CMOS sensor manufacturing operations to provide growth markets such as mobile phones and digital still cameras with CMOS sensors that combine high image quality with advanced processing speeds.

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According to Kammagamma, they say that Canon has developed a 52 megapixel CMOS sensor in APH-S size.

Here’s what they say in their abstract:

“We have developed a new CMOS image sensor having pixels of more than 52M in APS-H size. The CMOS image sensor has the most number of pixels known to date without stitching. The sensitivity of the monochromatic image sensor is 39000e-/lxï½¥s. The sensitivity of the colour image sensor (green pixel) is 16600e-/lxï½¥s. Pixel size is 3.2um x 3.2um. Random noise is 5.5e- with a saturation level of 24000e-. The CMOS image sensor has 5 x 5 random block readout mode and 4(2×2) adjacent pixels averaging mode. The reproduced image shows splendid high resolution.”

Below is a list of interesting questions and answers from Canon about the new sensor:

Question 1: What are the features of the new image sensor?

Answer 1: The image sensor features a newly developed pixel structure that is well suited to a
smaller pixel size, realizing a signal-to-noise ratio equivalent to that of SLR cameras. It is our understanding that 50 megapixels is the largest number of pixels ever to be fit on a sensor with these surface dimensions (31.6mm x 23.1 mm). The sensor enables high-resolution images to be extracted from the total image captured, making it well suited for the creation of new markets, such as inspection equipment. The sensor has a 5 x 5 random block readout mode for high-speed reading.

Question 2: What problems commonly arise when the pixel size is reduced? (Including such areas as circuit design, production, image quality, etc.)

Answer 2: Generally speaking, the following difficulties are encountered: sensitivity decreases,
the dynamic range decreases, and blending of colours increases. Also, because of the increase in circuit size, there is a tendency toward media delays and slower reading times. Furthermore, due to the further demands in the area of micro fabrication technology, there is also a tendency for yield rates to drop. To address these issues, we have carried out the efforts mentioned in A3 below.

Question 3: What have you done to address the problems that can occur when reducing the pixel size?

Answer 3: We reassessed the structure of the pixels and adopted a new structure that, even with a smaller pixel size, maintains sensitivity, dynamic range, and low colour blending. We
have also made progress in the area of micro fabrication. We also reassessed the circuit block, employing innovations in the area of circuit wiring and a high speed amp to secure a readout speed on par with current speeds.

Question 4: How much of an improvement was realized in terms of the accumulated charge per
pixel compared with conventional CMOS image sensors (taking into account the surface area of the new sensor)?

Answer 4: Compared with an existing product of the same image size, the new sensor achieves
an increase or 50 percent.

Question5: Compared with conventional CMOS image sensors, how much of an improvement in leakage to neighbouring pixels was achieved?

Answer 5: Leakage to neighbouring pixels was improved by about 10 percent.

Question 6: Why did you choose to make this sensor an APS-H size instead of a full-frame 35 mm size?

Answer 6: From a production standpoint, the APS-H size made it was easier to realize the
necessary miniaturization.

Question 7: Is this sensor also compatible with video?

Answer 7: While we have only incorporated limited functionality in this sensor at this stage, depending on the specifications we use, it would be possible to adapt this sensor for video.

Question 8: How far has development progressed? (Is there a prototype?)

Answer 8: We have created a prototype and have confirmed that it is capable of capturing
images.

Question 9: What challenges must be overcome before you will be able to mass produce this sensor?

Answer 9: We would need to increase the yield rate for the sensors, and make necessary
adjustments to match them to the characteristics of the lenses, which would be determined by the demands of whatever application the sensor would ultimately be used for.

Question 10: Compared with 10- and 16-megapixel sensors, how much more expensive would it be to manufacture this 50-megapixel sensor?

Answer 10: That would depend on the specifications and the yield rate.

Question 11: In what Canon products do you intend to use this sensor?

Answer 11: We have still yet to determine how this sensor might be used.

Question 12: What applications would this sensor be suited for in areas outside of Canon’s current product line-up?

Answer 12: Possible applications for this sensor include special surveillance cameras or
industrial-use inspection equipment.

Question 13: What merits would this sensor offer if used in a surveillance camera?

Answer 13: If used in surveillance cameras, the sensor would enable users to view an overall
scene while also enabling detailed close-ups from any given area within that scene.

Question 14: For use in surveillance cameras, what capabilities could such a sensor offer? (For
example, able to read newspaper text from a distance of XX meters.)

Answer 14: If equipped with a lens with sufficient resolving power, in principle, the sensor could
would make a car’s license plate number legible from a distance of 300 meters (approx. 330 yards).

Question 15: Are there any plans to market this sensor to third parties?

Answer 15: We have still yet to determine applications for this sensor. As such, that has still yet to be decided.

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Now here is some interesting piece of news from www.smh.com.au which claims that Kodak has developed sensors that can take photos in low light. To me this seems like they are increasing the ISO to about 2 -4 times the normal level, but what about noise. These are no mention of the noise or the image quality that comes out from these sensors and it will be interesting if this is just a marketing hype or a true breakthrough.

Unlike Fujifilm which has already proven their sensors can handle low light situations with the Fujifilm FinePix F series such as the award winning F30, Kodak yet to prove their claims.

Here are some of the comments:

“Eastman Kodak said it has developed a color-filter technology that at least doubles the sensitivity to light of the image sensor in every digital camera, enabling shutterbugs to take better pictures in poor light”.
“We’re talking about a two-to-four-times improvement in (light) sensitivity.”

“It’s often the simplest concepts that can have the most profound impact,” said Chute of IDC, a market research firm near Boston. “This could be revolutionary in terms of just changing that very simple filter on top of the sensor and basically allowing companies to use it in all different kinds of cameras.”

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Now here is a rugged camera, the Phantom Miro 3. Although it has a low resolution of 0.26 mega pixels, it has a super quick frame rate of 2200 frames per second!

The camera was revealed by Vision Research, their first member in a new line of Phantom high-speed digital cameras at the NAB in Las Vegas, Nevada, (16 - 19 April 2007) and SAE World Congress in Detroit, Michigan (16-19 April 2007), . The Phantom® Miro line is a compact, light-weight, rugged family of cameras targeted at industrial applications ranging from biometric research to automotive crash testing.

The first member of the family, the Phantom Miro 3, is optimized for applications such as Hydraulically Controlled, Gas Energized (HYGE) crash simulations used in the automotive industry. Rated to survive 100g acceleration (WOW!) this rugged camera can take 512 x 512 images at up to 2200 frames-per-second (fps). Reduce the resolution to 32 x 32 and achieve frame rates greater than 95,000 fps. With an ISO rating of 4800 (monochrome, saturation-based ISO 12232), the camera has the light sensitivity for the most demanding applications. With shutter speeds as low as 2 microseconds, the user can freeze objects in motion, eliminate blur, and bring out the image detail needed for successful motion analysis. The camera accepts any standard 1″ C-mount lens.

Selectable 8-, 10- or 12-bit pixel depth allows the user to choose the dynamic range that best meets the demands of the application.

The Miro 3 has a number of external control signals allowing for external triggering, camera synchronization, and time-stamping. The camera has both dynamic RAM and internal flash memory for non-volatile storage. Internal battery power allows the camera to be used in an un-tethered mode and ensures data survivability in case of loss of power.

The camera ships with a trial version of Image Systems’ TEMA Starter for Phantom motion analysis software.

Specifications

Key Features :

Resolution: 512 x 512

Frame rate: 2200 fps at 512×512 (0.26 mega pixels), >95,000 fps at 32×32

Minimum exposure: 2 microseconds

Sensitivity: 4800 ISO monochrome, 1200 ISO color (ISO 12232)

Built-in memory: 1GB or 2GB (optional)

Integrated flash memory: 2GB or 4GB (optional)

Pixel bit-depth: 8-bits standard, 10- & 12-bits optional

Record time: (max resolution, standard configuration) 16.3 seconds at 500 fps

Camera control: 10/100 Ethernet

Camera signals: Trigger, Strobe/IRIG out, Ready, Sync, IRIG in

Video out: PAL & NTSC

Lensing: 1″ C-mount

Size: 4.3″ x 2.6″ x 3.2″ (W x D x H); 11cm x 6.5cm x 8 cm

Weight: 2.0 lbs, 0.9 kg

Power: 20-32VDC, 12W

Battery: Poly-Lithium

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Here is an interesting diagram by ClarkVision which depicts his research on the correlation in mega pixels between the different 35mm films at variable ISO levels.

He says:

“While my research is preliminary, it does seem to agree with what people are saying, and because people look at different things (image smoothness versus spatial detail), it shows there is a lot of room for interpretation.”

It is the second diagram (see below) that’s really interesting as he tries to correlate film resolution against the different DSLR on the market. Based on his diagram, the sensors in some DSLR camera, notably the Canon 1Ds mark II have already exceeded the resolution in film.

Source: ClarkVision

Samsung has announced an 8.4 megapixel CMOS image sensor with a 1.4㎛pixel design at Samsung’s fourth annual Mobile Solution Forum. This is the worlds smallest CMOS sensor.

The new CMOS image sensor chip provides a very high signal to noise ratio which is a key measure of overall image quality.

This was achieved by implementing advanced light sensing features and minimized noise levels. Notably, an extended photo diode technology was implemented to achieve higher light sensitivity and saturation levels, resulting in an enhanced fill factor.

In addition, it provides the same image quality as the charge-coupled device (CCD) image sensors currently used in the majority of digital cameras and camcorders around the world. Since the new CMOS image sensor only uses one-tenth the power of a CCD image sensor, it should quickly replace CCDs in all three key applications-mobile phones, digital cameras and camcorders.

The CMOS image sensor product line of System LSI Division is one of the five major product areas that Samsung has been focusing on to enhance and balance the company’s overall competitiveness. Samsung’s present portfolio of CMOS image sensor technology spans across the range of 1.3 through 5 megapixel resolutions with the 8 megapixel CMOS image sensor expected to be available in the second half of this year.

The CMOS image sensor market is expected to show high demand for high-resolution devices. The current outlook toward 2009 shows a compound annual growth rate of over 90 percent for 3 megapixel and higher resolution devices over a four-year term from 2006 through 2009.

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