A Brand-New Application 
of Elixir and Pelemay: 
Real-time, High Resolution 
Satellite Image Processing

Transcript

1. A Brand-New Application of Elixir and Pelemay: Real-time, High Resolution

   Satellite Image Processing Susumu Yamazaki Univ. of Kitakyushu 1 © 2020 Susumu Yamazaki © 2012 Plataformatec © 2018 Susumu Yamazaki & Yuki Hisae

2. Susumu Yamazaki (ZACKY) • Twitter / GitHub / Gmail: ZACKY1972

   • Associate Professor • The Leader of the Nudge Social Implementation Research Center • at Univ. of Kitakyushu • Co-author of Pelemay • Co-organizer of ElixirConf JP 2 © 2020 Susumu Yamazaki

3. © 2020 Susumu Yamazaki Japan USA Far, far away… I’m

   here!

4. © 2020 Susumu Yamazaki ʆ Honshu Kyushu Japan I’m here!

   Shikoku Hokkaido

5. © 2020 Susumu Yamazaki Honshu Kyushu I’m here! Kitakyushu

6. Prologue 6 © 2020 Susumu Yamazaki

7. A long time ago in a galaxy far, far away…

   7 © 2020 Susumu Yamazaki

8. A long time ago in a galaxy far, far away…

   8 © 2020 Susumu Yamazaki I’m sorry but BGM is turned off due to copyright.

9. Who is Mr. Takayama? 9 © 2020 Susumu Yamazaki

10. Hisanobu Takayama • He is the CEO of minsora, Inc.,

    a company that has the philosophy, “Change structures of the space industries from the region. Make the outer space more fun and interesting!” • He has organized many projects on outer space, including ALMA telescope (see the upper figure), which is a radio telescope placed in Atacama, HTV (see the lower figure), which supplies resources to the space station, and promoting foundation of business on utilization of outer space. • Currently, he is conducting to create the Asia's first space port and city, and then a new market and ecosystem centered on the port, in Oita, Kyushu, Japan. • He has proposed joint research on utilizing SAR satellites to me. 10 © 2020 Susumu Yamazaki ©JAXA/NASA © NAO

11. What is SAR satellites? 11 © 2020 Susumu Yamazaki

12. What is SAR Satellites? • SAR: Synthetic Aperture Radar •

    They observe the Earth’s surface by microwave (see the right figure), not by radiant rays. • Because SAR is an active sensor unlike an optical passive sensor, they can observe the Earth’s surface even at nighttime when the sun doesn’t reach. • Microwave transmitted by them also passes through even cloud unlike radiant rays. 12 © 2020 Susumu Yamazaki © CRISP, 2001

13. How much observation power do SAR satellites have? 13 ©

    2020 Susumu Yamazaki

14. How much observation power do SAR satellites have? • SAR

    satellites can observe always the Earth’s surface even at nighttime and/or in bad weather due to above-mentioned their own principle. • Synspective, one of Japanese enterprise, will deploy 25 SAR satellites, which can identify a 1-3m (3-10 feet) square object on the Earth’s surface. • GeoEye-1 and WorldView-2, SAR satellites of USA, can identify a 50cm (1.6 feet) square object on the Earth’s surface. • iQPS, another of Japanese enterprise, will deploy 36 SAR satellites that can take photographs of almost any point in the world within 10 minutes, and conduct fixed-point observations at particular areas once every 10 minutes. 14 © 2020 Susumu Yamazaki

15. Amazing! What apps will be expected? 15 © 2020 Susumu

    Yamazaki

16. What apps will be expected? • Disaster preparation and recovery

    • Harvest predictions • Economic predictions • Natural environment protection and observation • Physical distribution management • Searching for mineral resources • And so on. 16 © 2020 Susumu Yamazaki

17. More detail! 17 © 2020 Susumu Yamazaki

18. What apps will be expected? • Disaster preparation and recovery

    • Harvest predictions • Economic predictions • Natural environment protection and observation • Physical distribution management • Searching for mineral resources • And so on. 18 © 2020 Susumu Yamazaki

19. App 1: Physical Distribution Management for Tourism 19 © 2020

    Susumu Yamazaki

20. © 2020 Susumu Yamazaki ʆ Kanmon area Honshu Kyushu ↓

    To Oita Prefecture (Space Port) I’m here!

21. Many Tourist Attractions in the Kanmon area 21 © 2020

    Susumu Yamazaki

22. History 22 © 2020 Susumu Yamazaki

23. © 2020 Susumu Yamazaki The end battle of the Genpei

    War at Dan-no-ura

24. © 2020 Susumu Yamazaki The duel at Ganryujima

25. © 2020 Susumu Yamazaki © nimame Kokura-jo (Kokura Catsle), Kitakyushu,

    Fukuoka, Japan

26. © 2020 Susumu Yamazaki © nimame Nagasaki Kaido, a road

    across Kyushu from Kokura to Nagasaki

27. © 2020 Susumu Yamazaki World Heritage Site of Meiji Restoration

28. © 2020 Susumu Yamazaki Unknown, Courtesy of Meiji Seihanjo, 1922

    Albert Einstein visited (1922)

29. Beauty 29 © 2020 Susumu Yamazaki

30. © 2020 Susumu Yamazaki Tsunoshima Bridge in Shimonoseki, Yamaguchi, Japan

31. © 2020 Susumu Yamazaki Hotel Nishinagato Resort near Tsunoshima Bridge

32. © 2020 Susumu Yamazaki Hotel Nishinagato Resort near Tsunoshima Bridge

33. © 2020 Susumu Yamazaki Hotel Nishinagato Resort near Tsunoshima Bridge

34. © 2020 Susumu Yamazaki Beautiful Blossoms

35. © 2020 Susumu Yamazaki Beautiful Blossoms

36. Culture 36 © 2020 Susumu Yamazaki

37. © 2020 Susumu Yamazaki Exciting Festivals

38. © 2020 Susumu Yamazaki Exciting Festivals

39. Venue of ElixirConf JP 39 © 2020 Susumu Yamazaki

40. © 2020 Susumu Yamazaki ElixirConf JP is held here Please

    attend and enjoy it if it will resume! I’m here!

41. But, after the outbreak of Coronavirus,… 41 © 2020 Susumu

    Yamazaki

42. After the outbreak of Coronavirus… • Tourism has been damaged

    seriously, because of preventing tourists from moving between areas as well as between countries, and from dinning at restaurant during the tour without any countermeasures against contagion. • It will be important to make tourism profitable by making it efficient, without reducing its attraction and safety. • I hypothesis that transportation during a tour is changed from public one to private one by vehicles. • Navigation for tourists smoothly is one of important measures. • But, gathering personal information by smartphones is not welcome. 42 © 2020 Susumu Yamazaki

43. Smooth navigation by satellites • SAR satellites has a potential

    to identify all of vehicles and obstacles on roads and parking lots observable from the outer space, once every 10 minutes, even nighttime and/or in bad weather. • So, it can be realized to implement a traffic control system that can identify congestion on every roads and parking lots using image recognition technology to images from satellites. • Of course, it can be realized without any personal information and additional sensors on the roads and parking lots! • I’d like to be going to make this system integrated with other navigation systems, such as Google Maps, in future. 43 © 2020 Susumu Yamazaki

44. App 2: Disaster Preparation and Recovery 44 © 2020 Susumu

    Yamazaki

45. Sediment disasters are more likely to occur in Japan See

    the right figure: • The x-axis of it is year. • The y-axis of it shows the total flooded area, the total amount of damage caused by flood, and the ratio. • The blue line shows the flooded area of Japan (square kilometer). • The green line shows the total amount of damage caused by flood of Japan (billion Yen, normalized with the value in 2000). • The gray lines shows the ratio of the total amount of damage to the total flooded area multiplied by 1,000 and the trend line of it, which represents seriousness of the flood damage. 45 © 2020 Susumu Yamazaki The trend line of seriousness of the flood damage has a positive slope!

46. How serious is a menace of flood damage? 46 ©

    2020 Susumu Yamazaki

47. A Menace of Flood Damage 47 © 2020 Susumu Yamazaki

    This is the street view of Toho small town, Fukuoka, Japan, when the flood damage of a very heavy outbreak of rain that poured in west Japan in 2017, which forced us to pay 536,000,000,000 Yen (about 5 billion dollars). You can see this at https://goo.gl/maps/eM6cpL4LpYBMyFig7

48. Why is flood damage so serious in Japan? 48 ©

    2020 Susumu Yamazaki

49. Why is flood damage so serious in Japan? Rivers in

    Japan are much more rapid than those in the US and Europe. See the right figure: • The x-axis of it is the distance from the estuary (kilometer). • The y-axis of it is the elevation difference from the estuary (meter). • This ellipse surrounds Japanese rivers. 49 © 2020 Susumu Yamazaki Japanese Rivers are like waterfalls! This is because the total area of Japanese mountains and hills is 70% of the whole country.

50. Why is flood damage so serious in Japan? In addition,

    heavy rainfall becomes more likely in recent years. See the right figure: • The x-axis of it is year. • The y-axis of it is the frequency of rainfall over 50 mm per hour in Japan. • The blue line shows the frequency for each year. • The red line shows the trend line of it. 50 © 2020 Susumu Yamazaki The frequency of heavy rainfall has been increasing! So, flooding has become more likely in Japan in recent years, though flood control has been developed.

51. What can satellites support for solving to flood issues? 51

    © 2020 Susumu Yamazaki

52. What can satellites support for solving to flood issues? We

    can find out where there might have been a landslide by following the steps: 1. Take pictures of places with potential heavy rainfall according to the weather forecast, before the heavy rainfall. 2. Take pictures of the places again, during and after the heavy rainfall. 3. Find image differences of the photos before and after the heavy rainfall. Very easy! All we have to do is to do it in time. 52 © 2020 Susumu Yamazaki

53. What is outcome that is expected? 53 © 2020 Susumu

    Yamazaki

54. Potential outcome Such a system to detect sediment-related disasters every

    time even in nighttime and/or in bad weather • Can notify the damage caused by flood quickly to the disaster countermeasures office. • May find houses buried under sand and mud quickly to rescue people from it. • Enables quick and accurate recovery planning by the disaster countermeasures office. We can obtains many benefits by it, as a result. 54 © 2020 Susumu Yamazaki

55. Integration 55 © 2020 Susumu Yamazaki

56. Integration Usually: Physical Distribution Management for Tourism In Emergency: Disaster

    Preparation and Recovery 56 © 2020 Susumu Yamazaki Usually In Emergency

57. A Brand-New Application: Real-time, High Resolution Satellite Image Processing 57

    © 2020 Susumu Yamazaki

58. A Brand-New Application: Real-time, High Resolution Satellite Image Processing 58

    © 2020 Susumu Yamazaki I’ll build an ecosystem using satellites that enables the proposed apps as well as other useful apps, to be developed!

59. BTW, how will they be related to Elixir? 59 ©

    2020 Susumu Yamazaki © 2012 Plataformatec

60. We need more POWER! 60 © 2020 Susumu Yamazaki

61. We need more POWER! • Suppose to utilize full potential

    of SAR satellites. • Surface area of the Earth is 510,100,000 (five hundred ten million and one hundred thousand) square kilometer. • If the resolution of SAR satellites is supposed to be 50 centimeter, the number of the pixels of the image of the entire Earth will be 2,040,400,000,000,000 (two quadrillion, forty trillion and four hundred billion). • This equals to approximately 246,000,000 (two hundred forty six million) 4K images. • The memory size of raw data of it will be several PB, which equals to several thousands TB! • Such huge images may come every 10 minutes from satellites! • Too huge to be transmitted, processed and memorized, even if using supercomputers… • So, current available computational power in the entire world is not enough to utilize full potential of SAR satellites. 61 © 2020 Susumu Yamazaki

62. Limit the potential of satellites • Within limited local area

    when observing usually, for example, the Kanmon area; • Within some areas as large as the usual observing area, when observing in emergency; • In order to realize the system with limited available computer resources… Still it requires quite large computational power. 62 © 2020 Susumu Yamazaki ʆ Kammon area about 1,200 square kilometer

63. A NEW HOPE: Elixir and Pelemay 63 © 2020 Susumu

    Yamazaki © 2012 Plataformatec © 2018 Susumu Yamazaki & Yuki Hisae

64. What’s Pelemay? 64 © 2020 Susumu Yamazaki © 2018 Susumu

    Yamazaki & Yuki Hisae

65. What’s Pelemay? •Pelemay is a native compiler for Elixir, which

    generates SIMD instructions. It has a plan to generate for GPU code. https://github.com/zeam-vm/pelemay •Current Pelemay’s version is 0.0.13. •Supported Platforms: •x86_64 and ARM / macOS, Linux and Nerves •Elixir 1.9 to 1.10 / OTP 20 to 22 •See the upper right figure, which shows sample source code using Pelemay. •See the lower right figure, which shows an additional description to mix.exs. 65 © 2020 Susumu Yamazaki © 2018 Susumu Yamazaki & Yuki Hisae

66. How much effective is Pelemay? 66 © 2020 Susumu Yamazaki

    © 2018 Susumu Yamazaki & Yuki Hisae

67. How much effective is Pelemay? •Pelemay makes Elixir much faster!

    •See the right figure: •This shows speed up ratios of the benchmarks by Pelemay to Enum, which is measured by Benchfella. •The speed up ratios of integer calculation, float calculation and string replacement by Pelemay are 2.25x, 4.48x and 3.85x to Enum. •Furthermore, it has more potential to make Elixir much faster, if now-going research and development will be completed! 67 © 2020 Susumu Yamazaki © 2018 Susumu Yamazaki & Yuki Hisae

68. A NEW HOPE: Elixir and Pelemay 68 © 2020 Susumu

    Yamazaki © 2012 Plataformatec © 2018 Susumu Yamazaki & Yuki Hisae

69. A NEW HOPE: Elixir and Pelemay 69 © 2020 Susumu

    Yamazaki © 2012 Plataformatec © 2018 Susumu Yamazaki & Yuki Hisae • Elixir has enough potential to process concurrency for transmission. • Elixir and Pelemay will provide enough parallel computation for processing.

70. How will Elixir and Pelemay process and transmit such too

    huge images? 70 © 2020 Susumu Yamazaki © 2012 Plataformatec © 2018 Susumu Yamazaki & Yuki Hisae

71. TO BE CONTINUED…→ 71 © 2020 Susumu Yamazaki Look forward

    to my next presentation! Feel free to contact me @zacky1972