BEGINNINGS AND EDUCATION

Fumio Okano was born on August 15, 1952, in Ibaraki, Japan. He received B.S.(1976), M.S.(1978), and Ph.D.(1996) degrees in electrical engineering from Tohoku University, Sendai, Japan. His Ph.D. thesis was entitled “Research on Architectures for High-definition Television Image Capture Systems.”

Okano joined Japan Broadcasting Corporation (NHK) in 1978. From 1978 to 1980, he calibrated and configured cameras and monitors for a broadcast station as a video engineer. Programs produced at the station were viewed by a very large number of people, so the video used in them needed to be of very high quality. Okano had an uncompromising attitude toward image quality, reflecting his experience as a video engineer. This attitude played a key role in his research efforts over the subsequent years. In the following sections, I will summarize the main contributions of Fumio Okano.

HIGH-DEFINITION TELEVISION SYSTEM

In 1981, Okano was transferred to the NHK Science and Technology Research Laboratories (STRL), where he researched high-definition television (HDTV) cameras and HDTV systems.^3-5 All of the devices comprising an HDTV system, from those for image capture to those for display, needed to be developed. In particular, image capture devices needed high performance with enough flexibility to handle the various applications and image processing tasks envisioned. Okano made five important contributions to increasing the performance of HDTV cameras: an auto-beam-focus method, registration compensation, focus-aid signals, highly sensitive handheld cameras, and a pixel-offset method.

Maintaining good beam focus is an important factor in obtaining high resolution images from an imaging tube. Okano analyzed the effects on the output signal, of small signals superimposed on the deflection waveform of the imaging tube. He found that the effect on the output signal clearly depended on the beam focus state. He used this finding to devise a method for maintaining good beam focus. This simplified the work of tuning cameras and improved camera performance.

Some color cameras that use imaging tubes separate the incoming light into red, green, and blue components before image capture because doing this provides higher resolution. A television signal is then generated by combining the signals from these three components. However, any offset in their positions causes problems such as colored outlines in the captured image or a loss of resolution in the luminance signal. Okano developed a method for avoiding problems: the relative offsets of each color image are computed using cross-correlation functions between the red, green, and blue images, and compensation is made for any offsets.

As camera resolution increases, focusing must be done more accurately. Cameras are equipped with viewfinders that are used for focusing. Small viewfinders are used for compact cameras, but small view finders have lower resolution, which makes it difficult to focus accurately. To compensate for this, Okano developed a method that visually enhances edges in the image by causing them to flicker. This focus-aid signal makes focusing easier.

Okano used these three technologies (auto-beam focus, registration support, and focus-aid signal) to develop a hand-held HDTV camera. The camera incorporated three high-gain avalanche rushing photoconductor (HARP) image sensors, which are extremely light-sensitive. This camera was used in coverage of the Seoul Olympics.

Okano also prototyped an HDTV camera using 2/3 inch CCDs developed for high-picture-quality National Television System Committee (NTSC) system cameras. This camera captures the green signal, by using two CCDs with relative positions offset by half a pixel in the horizontal direction. The prototype Hi-Vision camera was able to capture images with resolution of over 900 TV lines. This showed that HDTV camera configurations using image sensors with fewer pixels were possible.

Okano’s R&D showed that the new Hi-Vision television system had applications beyond broadcasting, including industries such as film, print, and medicine.

SUPER HI-VISION SYSTEM

The Super Hi-Vision (8K/SHV) system (“ultrahigh-definition television system” in standardization terminology) is attracting much attention as the next-generation broadcasting system. Okano began development of SHV at NHK.^6,7 SHV has four times the resolution of HDTV in both the horizontal and vertical directions and is seen as the ultimate 2D video system. In deciding the specifications for Super Hi-Vision, Okano conducted many evaluation tests and theoretical studies. In the initial stages, he prototyped a Super Hi-Vision camera using the pixel-offset method, which uses two image sensors to capture the green signal and one each for the blue and red signals. This camera used the technique he cultivated when developing HDTV cameras. The Super Hi-Vision system was exhibited at the 2005 World Exposition held in Aichi Prefecture. Programs were presented on a 600-inch screen over six months starting in March 2005 and were enjoyed by 1.56 million visitors. The Kyushu National Museum, which opened in October 2005, is equipped with a permanent SHV theater (350-inch screen). Super Hi-Vision was subsequently introduced to many people through events such as the National Association of Broadcasters (NAB) show, the International Broadcasting Convention (IBC), and public viewings of the 2012 Olympics in London.

Figure 1.

Photograph of Fumio Okano taken in 2004 at the Kyushu National Museum under construction.

THREE DIMENSIONAL TELEVISION SYSTEM

Okano’s enthusiasm for R&D on new video systems did not stop with Super Hi-Vision, the ultimate 2D video system. He also had a passion for developing 3D video systems and left an important legacy in that field as well.^{1,2 8-26}

With respect to stereoscopic images, he was a leader in the study of such issues as the effects of stereoscopic viewing on visual function, excessive compression of 3D images in the depth direction, and the phenomenon of 3D images appearing unnaturally small. He also developed a method for converting imagery captured by the Kaguya lunar orbiter (also known as the Selenological and Engineering Explorer, or SELENE) into stereoscopic video. Kaguya captured motion video as it moved in a direction perpendicular to the screen. Images with a pseudo-horizontal parallax were created y rotating the captured images 90 degrees and combining two images taken at different times. The 3D images of the moon captured in this way were exhibited at NAB in 2009 and were very popular. Okano had many such ideas that were technically sound. His idea for converting the video captured by Kaguya into stereoscopic images exemplifies his being an excellent “ideas man”.

Okano also conducted R&D in the field of holography for application to building 3D television systems. It is possible to display moving 3D images by displaying interference patterns on an LCD panel. It is possible to generate high-order diffraction images by displaying interference patterns on an LCD panel, and Okano led development on equipment that expanded the range of where 3D images can be viewed. He also led the development of methods for avoiding the use of coherent light in image capture, by using information obtained with integral photography (IP) image capture equipment to generate interference patterns computationally.

Okano also left a legacy in the field of IP, which was proposed by Lippmann in 1908 as a 3D photography technique not requiring glasses for viewing. After Lippmann’s proposal, various theoretical studies and attempts to improve image quality were made, but little progress was made on research applying IP to a television system. Since NHK is a broadcasting corporation, Okano led the R&D on IP from its initial stages toward building a 3D television system. One requirement for such a system is to display motion 3D images in real time. In 1997, Okano showed that motion 3D images can be both captured and displayed in real time using a Hi-Vision camera, liquid crystal display (LCD), and lens array. However, at that time, the problem of creating pseudoscopic images, which are reversed in the depth direction relative to the subject, had not been solved yet. In 1999, in order to avoid the pseudoscopic image problem, he built prototype equipment using a gradient-index lens array. This made it possible to display 3D images that were correct in the depth direction in real time. This was a major advance in the development of an IP television system. Later, IP capture and display equipment was prototyped using 2000 scan lines and SHV video systems, improving the image quality.

Figure 2.

Photograph of Fumio Okano taken in 2008 at the NHK STRL Open House.

Developing such 3D imaging technologies, from capture to display, requires knowledge and experience that is both broad and deep. Okano had both the knowledge and experience required. He was able to utilize his experience as a video engineer and his experience in developing HDTV and Super Hi-Vision technology to make such great progress in the field of 3D video.

CLOSING REMARKS

The Hi-Vision technology that Okano worked on is now enjoyed by people around the world. The video parameters for Super Hi-Vision are being standardized by the International Telecommunication Union—Radiocommunication Sector (ITU-R) and the Society of Motion Picture and Television Engineers (SMPTE), and practical implementation is not far away. Okano also made great contributions to the application of 3D imaging technologies to television systems, enabling major advances in 3D television systems.

In 2009, Okano moved most of his activity to NHK Engineering Systems, Inc., where he worked in management while vigorously pursuing research. He was still hard at work when he passed away in November, 2013.

Okano’s leadership in these various efforts will be greatly missed. He will be remembered for his enduring contributions and innovations in the field of television technology.

Okano leaves behind a loving family – his wife, Hiromi, and two children. He will be deeply missed by all of his family, friends, and colleagues.