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Nikon Z9 ‘Dual-Stream’ Tech Records and Displays Images with No Lag

Nikon Z9 'Dual-Stream' Tech Records and Displays Images with No Lag

Nikon has published a short video that further explains the “Dual-stream” technology in its upcoming Z9 flagship camera, which it says will always assure an accurate reality-to-viewfinder experience.

The Dual-stream technology is part of Nikon’s technology for what it bills as a “real-live” viewfinder experience in the Z9. The company says that the tech is only made possible thanks to the combination of the newly-developed stacked CMOS sensor and the EXPEED 7 image-processing engine, which allows photos to be displayed on the electronic viewfinder or LCD monitor (whichever is being used to monitor capture) as well as record that still-image data to a memory card at the exact same time.

Nikon says this differs from other “blackout-free” shooting experiences from competitors as other implementations have some kind of a delay between what is seen and what is captured.

“Unlike conventional blackout-free shooting that displays the same frame to prevent interruption of the finder image, this viewfinder continues to display the actual movement of the subject within the scene, so that every single moment can be smoothly and continuously confirmed with no skipped frames or loss of view,” Nikon claims.

“Because this is achieved even when continuous shooting is repeated over a short period of time, it is ideal for scenes in which tracking of quickly moving subjects is required, such as during sports, allowing users to reliably capture the finest moments without missing any shutter opportunities.”

The video above shows that the pixel array captures image data and moves it through to the camera’s circuitry and simultaneously then streams that data to two separate outputs, one to the viewfinder or LCD and one to the memory card.

Nikon Z9 'Dual-Stream' Tech Records and Displays Images with No Lag 1

“Dual-stream technology processes data for live view and recording separately and in parallel, which makes the Real-Live Viewfinder possible,” the company further explains.

The company says this particular implementation delivers a smooth view that reveals every single moment of the capture, including those previously missed by conventional electronic viewfinder systems or those that block the view due to a mirror in DSLRs.

The video also shows a “competitor” camera that skips and repeats some frames side by side with Nikon’s implementation, though the company does not state which camera it is comparing the Z9 experience to.

The Nikon Z9 features a 45.7-megapixel stacked CMOS sensor, 8K video capability, and is the first professional full-frame mirrorless camera to be released without a physical shutter. It is scheduled to become available to purchase by the end of the year for $5,500.

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Groundbreaking Graphene Camera Records a Heart’s Electrical Signals

Groundbreaking Graphene Camera Records a Heart's Electrical Signals

Scientists have been able to capture the real-time electrical activity of a beating heart using a sheet of graphene to record an image. The result is almost like a video camera, and the generated images show the electric fields that trigger a heartbeat.

Graphene is a material that has a high ceiling of potential that could be used to make a wide range of products and services. As explained by Verge Science, graphene has the capability to bring the world anything from bulletproof armor and space elevators to making the internet run faster and advancing medical science.

It is that last bit about advancements in medical science that this new research report from a collaboration between two teams of quantum physicists at the UC Berkeley and physical chemists at Stanford University.

The use of graphene — which is a material that is made of a single layer of carbon atoms arranged in a lattice — in this way shows its use as a wholly new type of sensor that will be useful for studying cells or tissues that generate electrical voltages. Previously, researchers were able to do this with electrodes or chemical dyes, but these had the limitation of only measuring the voltage at a single point.

A graphene sheet can measure voltage continuously and over all of the tissue it covers.

“Because we are imaging all cells simultaneously onto a camera, we don’t have to scan, and we don’t have just a point measurement. We can image the entire network of cells at the same time,” Halleh Balch, one of three first authors of the paper, says. Balch recently received her Ph.D. from UC Berkeley’s Department of Physics.

According to the published research report, the graphene sensor can work with existing standard microscopy techniques as well, expanding its usability.

To image a heart, the researchers placed a sheet of graphene above a waveguide and below a chamber that held a sample of tissue. A waveguide is a structure that, as it sounds, guides waves with minimal loss of energy by restricting the transmission of the energy into one direction.

Laser light was aimed into the waveguide through a prism, reflected off the graphene, and bounced inside the waveguide again before it exits and is recorded by a camera (specifically noted as a CCD camera). The internal reflections inside the waveguide amplify the response of the graphene to the electrical field of the sample and thus visualize the electrical current.

Groundbreaking Graphene Camera Records a Heart's Electrical Signals 2

The sequence of images, separated by five milliseconds, then shows changes in the electrical field pattern on the surface of the heart during a single beat.

Groundbreaking Graphene Camera Records a Heart's Electrical Signals 3

Feng Wang, a UC Berkley professor of physics and senior author of the paper says that this is perhaps the first example of using an optical readout of 2D material to measure biological electrical fields.

“People have used 2D materials to do some sensing with pure electrical readout before, but this is unique in that it works with microscopy so that you can do parallel detection,” he says.

“This study is just a preliminary one; we want to showcase to biologists that there is such a tool you can use, and you can do great imaging. It has fast time resolution and great electric field sensitivity,” Jason Horng, a UC Berkeley Ph.D. and the third first author of the research report. “Right now, it is just a prototype, but in the future, I think we can improve the device.”

The full research report from the two teams of scientists can be read in the Nano Letters journal.


Image credits: Photos and schematics by Halleh Balch, Allister McGuire and Jason Horng

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