>Sounds reasonable for now. Thinking of making the number of cameras customizable. Certainly. The number of cameras is somewhat arbitrary, the main feature desired is an arrangement that can record the entire 360 degree horizontal landscape. 6 cameras should be sufficient with the (older) 4x3 screen aspect ratio. With the modern HD's 16 x 9 ratio, it's conceivable that a 4 camera system would be sufficient, and probably 5 cameras. The compression hardware allowing for as many as 6 cameras should be more than plenty, and there would not be any need to have all cameras installed at any given time. This same system could also be used to run a fixed system, perhaps mounted on a high location. > Any thoughts on supporting a standalone phone app, on the software side? I think the App running on the smartphone device will control the rest of the device. Most of the processing (video compression) should be done by the central board, not by the smartphone. I think the smartphone would be able to run anything you ordinarily would want to run, such as telephone service. >You mentioned a lot of experience making new hardware designs. Are you imagining designing a custom board? I imagine that would open options up a lot but it sounds like a big investment of effort and time for most people. Yes, I think that a custom board will be very desireable, and probably necessary. Is it possible that an existing design compresses the output of 6 HD video cameras? I haven't looked, but it seems unlikely. I've just started looking at the Qualcomm Snapdragon series of microprocessors. [1]https://en.wikipedia.org/wiki/Qualcomm_Snapdragon Their most recent devices use 8-cores. Perhaps that will handle the compression of 3 HD video devices, but I don't expect to rely on that. Three, or possibly two such physical CPUs (with few other responsibilities) will probably easily handle 6 HDTV cameras. PC board layout these days is rather easily done. It shouldn't be a problem. A six-layer PCB, with components on both sides of the board, should be more than sufficient. "Snapdragon is a suite of [2]system on a chip (SoC) [3]semiconductor products for mobile devices designed and marketed by [4]Qualcomm Technologies Inc. The Snapdragon [5]central processing unit (CPU) uses the [6]ARM [7]RISC instruction set. A single SoC may include multiple [8]CPU cores, an [9]Adreno [10]graphics processing unit (GPU), a [11]Snapdragon [12]wireless modem, a [13]Hexagon [14]Digital signal processor (DSP), a [15]Qualcomm Spectra [16]Image Signal Processor (ISP) and other software and hardware to support a smartphone's [17]global positioning system (GPS), camera, video, audio, [18]gesture recognition and [19]AI acceleration. As such, Qualcomm often refers to the Snapdragon as a "mobile platform" (e.g., Snapdragon 865 5G Mobile Platform). Snapdragon semiconductors are embedded in devices of various systems, including [20]Android, [21]Windows Phone and [22]netbooks.^[23][1] They are also used in cars, wearable devices and other devices. In addition to the processors, the Snapdragon line includes modems, wi-fi chips and mobile charging products." [end of quote] It will probably not be possible to send more than a tiny fraction of this data directly to the Internet, so I anticipate sending maybe 1 frame/second for each camera, to be stored remotely. I've read that eventually, 5G technology will be able to transfer 10 gigabits/second, but I doubt that this will be kept up in a crowd of thousands of people, many of whom will be using their own cell phones. >You can also compress it super-low quality when quick motions matter. Yes, that's possible. As with many things, there will always be a trade-off in these matters. According to this, [24]https://en.wikipedia.org/wiki/Wi-Fi , WiFi 6 has a link rate of between 600-9608 megabits/second. 18 gigabytes per hour (what I calculated as 3 gigabyte/camera/hour, with 6 cameras) is 40 megabits/second. According to this, [25]https://en.wikipedia.org/wiki/4G 4G was/is supposed to handle as much as 1 Gbit/second. But in a crowd of smartphone-users, what this will translate to 'in real life' is questionable. The smartphone might also be linked to a nearby confederate (is that word too anti-PC these days?) by WiFi, whose system might mirror as best as possible the video material being collected. One goal is to ensure that complete destruction of the system will not lose all the data collected. If the location of the event was anticipated, perhaps a remote data-collection box could be installed, which would act as a safe data backup. >Any thoughts on a data protocol with wifi peers? [26]https://datproject.org [27]https://gnunet.org . I've also found [28]https://git-annex.branchable.com which uses git of course [29]https://scuttlebutt.nz which is nodejs and json based but has nice data preservation goals, a modified blockchain might work. Haven uses the signal private messenger protocol. A local webserver could do a simple handmade one, I suppose; harder to make many backups. Hey, I never was a 'software guy'. This is well beyond my ability to choose. But one advantage of implementing a WiFi transmission is that there may be less competition for data transfer during a protest/demonstration in the WiFi bands, rather than cell-phone data bands. The actual control of the camera system might be done remotely: The person wearing the system shouldn't be expected to do anything other than being a camera platform. >Sounds good for journalists working with a team. This kind of system would probably have an even bigger market to journalists and news crews. I don't expect it to substitute for traditional video cameras, but its presence would tend to guarantee that most information gets collected. It would tend to protect the news crews, because it would store a record of any attacks on them. Jim Bell >Sorry I jumped excitedly on your project like this. I can do some software coding but need to work with others to take something to completion. That difficulty is also why I think of reusing existing work where possible. We should welcome all assistance. If things seem to be coming along, I will probably announce this as a project about July 19 2020 at Las Vegas, [30]http://anarchovegas.com/ I believe that one theme of the event is development of technology. I'd also like to be able to announce a project of a replacement/competition for the TOR anonymization system, perhaps using a Raspberry Pi 4 CPU. The main obstacle to that at this point is finding somebody who would commit to write the appropriate software. I will probably announce both as projects, and see what kind of support we get. Jim Bell On Thursday, June 11, 2020, 02:31:06 PM PDT, Karl wrote: Jim, I'm reading your e-mail while replying. On Thu, Jun 11, 2020, 4:43 PM jim bell <[31]jdb10987@yahoo.com> wrote: "I am interesting in participating in designing and building one. It helps me to set a norm of speaking concisely and to the point, as reading can be hard for me when working. I am sorry if I have skimmed over something already said. Have you started any projects?" I've done a substantial amount of electronics in the 1970's and to the early 1990's, but I haven't done an electronics project since then. Not that I couldn't pick it up quickly: The major thing I'm missing is knowledge of the current set of devices available and construction techniques. I designed and built a constant-temperature bath in the ealry 1970's, also a 4-digit audio frequency counter, also a 4.5 digit digital voltmeter. In 1977 I built a "Dyna-Micro" microprocessor trainer, from the design in Radio-Electronics magazine. I was born in 83 and I believe I built a robot hand by following a design in Radio-Electronics as a child. I was self and family taught, but mostly software. [32]Single-board computer Single-board computer Unlike a desktop personal computer, single board computers often do not rely on expansion slots for peripheral f... [33]Dyna-Micro Single Board Computers Dyna-Micro Single Board Computers This is a discussion forum about vintage computer collecting, use, restoration and display powered by vBulletin.... I added to that with a custom-PC board with 8K by 8 memory, which actually seemed like a lot of memory at that time! Starting in 1978, I designed and built my custom-bus Z-80 microprocessor computer which at one point had about 600 IC's, mostly wire-wrapped. My father and I set up the ability to make 2-sided PC boards around 1972, but since we couldn't plate-through the holes, actually assembling such a board was a bit tedious. I built two 32K by 8 DRAM cards using Motorola 4k x 1 6605 DRAM chips, later replacing them with static RAM. [34]MCM6605A Datasheet | Motorola Semiconductor - Datasheetspdf.com In hindsight, I decided that I should have used one of the 16k x 1 DRAMs that had become available. MCM6605A Datasheet | Motorola Semiconductor - Datasheetspdf.com MCM6605A 4096-Bit DRAM datasheet pdf provided by Datasheetspdf.com Datasheet pdf Search for MCM6605A. In 1980, I invented the solid-state disk, I called it a "SemiDisk", and in late 1981 I started a company which built them for 10 years, for the S-100 bus, the TRS-80 Model II, the IBM PC, and the Epson QX-10. The first three started as 512k byte cards, with software that implemented a virtual disk. [35]the consumer SSD guide on StorageSearch.com the consumer SSD guide on StorageSearch.com [36]S100 Computers - SemiDisk History S100 Computers - SemiDisk History S100 Computers You are very experienced with electronics. In 1990, I designed and built a device which used 76 IRLEDS to flash, activating the Opticom traffic control system to turn red traffic lights into green traffic lights. Had I gone into major production, I would have used as its motto: "It's the most fun you can have in a moving car !!!". That sounds awesome. HOW I FORESEE THE PERSONAL BLACK BOX: I see a central box, about the size and shape of a common smartphone, but with no user interface. It will include connectors to: 1. USB, to a standard, commercial smartphone. 2. To the camera stack, 4-6 HD cameras. (About 3 gigabytes per hour per camera.) 3. To a battery pack. 4. To a SSD. At 3 gigabytes/camera/hour x 6 cameras, about 18 gigabytes per hour. So, a 1 terabyte SSD should be sufficient, if its data transfer rate is enough. The central box will probably include 2-3 multi-core microprocessors, and its main task will be taking the data outputs of the cameras, compressing them, and sending the result to the SSD. Sounds reasonable for now. Thinking of making the number of cameras customizable. Any thoughts on supporting a standalone phone app, on the software side? You mentioned a lot of experience making new hardware designs. Are you imagining designing a custom board? I imagine that would open options up a lot but it sounds like a big investment of effort and time for most people. It will probably not be possible to send more than a tiny fraction of this data directly to the Internet, so I anticipate sending maybe 1 frame/second for each camera, to be stored remotely. I've read that eventually, 5G technology will be able to transfer 10 gigabits/second, but I doubt that this will be kept up in a crowd of thousands of people, many of whom will be using their own cell phones. You can also compress it super-low quality when quick motions matter. The smartphone might also be linked to a nearby confederate (is that word too anti-PC these days?) by WiFi, whose system might mirror as best as possible the video material being collected. One goal is to ensure that complete destruction of the system will not lose all the data collected. If the location of the event was anticipated, perhaps a remote data-collection box could be installed, which would act as a safe data backup. Any thoughts on a data protocol with wifi peers? [37]https://datproject.org [38]https://gnunet.org . I've also found [39]https://git-annex.branchable.com which uses git of course [40]https://scuttlebutt.nz which is nodejs and json based but has nice data preservation goals, a modified blockchain might work. Haven uses the signal private messenger protocol. A local webserver could do a simple handmade one, I suppose; harder to make many backups. The actual control of the camera system might be done remotely: The person wearing the system shouldn't be expected to do anything other than being a camera platform. Sounds good for journalists working with a team. This kind of system would probably have an even bigger market to journalists and news crews. I don't expect it to substitute for traditional video cameras, but its presence would tend to guarantee that most information gets collected. It would tend to protect the news crews, because it would store a record of any attacks on them. Jim Bell Sorry I jumped excitedly on your project like this. I can do some software coding but need to work with others to take something to completion. That difficulty is also why I think of reusing existing work where possible. On Wednesday, June 10, 2020, 12:26:08 AM PDT, Karl <[41]gmkarl@gmail.com> wrote: It's obvious that people who are oppressed by local authorities need a personal black box. I am interesting in participating in designing and building one. It helps me to set a norm of speaking concisely and to the point, as reading can be hard for me when working. I am sorry if I have skimmed over something already said. Have you started any projects? I have started [42]https://github.com/xloem/openrealrecord (nodejs, messy) and [43]https://github.com/xloem/libgame/blob/wip-1/source/stream-up.cp p (c++ livestreams data to sia skynet with hash identifiers). openrealrecord has an open [44]bountysource.com bounty of I think a little over $1000 that a contributor never claimed, left over from back when I had money. I also started developing videorecording in guardianproject's haven app towards this goal [45]https://github.com/guardianproject/haven/pull/418 . I'd like to build this in a way that quickly gets it usable by average people. Once it is easy to use and stable the people who can make the most use of it can share it among each other and more developers may contribute exponentially. Am I on the same page as you? On Mon, Oct 1, 2018, 2:16 AM jim bell <[46]jdb10987@yahoo.com> wrote: A few weeks ago, I got done binge-watching every episode of NCIS, and am now up to Season 4 of Criminal Minds. Naturally, this induces a bit of what I'll call cinematic paranoia. In what seems to be a majority of episodes, a victim gets attacked, usually ends up dead, and the plucky investigators are stuck trying to figure out what happened. Naturally, they usually do, but only after about 45 minutes of high-tension showtime. It occurs to me that what people may need, for physical security, would be what might be called a "personal black box", analogous to an airplane flight recorder. Or, a civilian version of a cop's body-cam. Any modern smartphone would have the basics of such a device: A high-resolution camera, microphone, and a huge amount of storage. And a quick 911-call if necessary. The mere possession and use of such a device would probably deter the large majority of potential attackers. And even if it does not completely protect a given user, it would allow far more easy identification of the perpetrator. Parts of this, of course, are not a new idea. [47]https://www.sparkfun.com/news/702 [48]https://www.theglobeandmail.com/technology/gadgets-and-gear/gadget s/your-own-personal-black-box/article4300839/ [49]https://www.zdnet.com/article/fitbit-activity-data-as-evidence-in- court-wearables-serve-as-personal-black-boxes/ [50]https://www.medgadget.com/2005/08/cpod_a_personal.html [51]https://newatlas.com/australia-black-box-flight-recorder-soldiers/5 1267/ However, storage is not enough: In use, in some instances, an attacker would presumably be aware enough to take or break the device, so some sort of continuous or discontinuous upload of the data could be done, to be available no matter what else happens. Say, a frame per second when nothing seems to be happening, and a greater rate when triggered somehow. Could a heart-rate monitor be employed, sensed one axis of the phone's accelerometers? Or if the wearer falls down? Or if a sufficiently-loud noise is heard, etc. Or if a trigger-word is spoken a la Siri? Can the data transfer be made economical? Even an average of 1 megabit/second would be over one gigabyte during a 3 hour usage per day. That's substantially greater than most people currently use. One possibility is that the phone could upload the data to the cell phone company, where it could be "parked" for a few seconds or minutes. If nothing happens to the phone to cause a trigger (some sort of attack) the phone could instruct the cell phone company to abandon the data. Conversely, if a trigger occurs, the cell phone company would move 100% of the data to a backup system for later retrieval. Presumably, the cell phone company would offer discounted rates for such transfers, and only offer that service if the local service is sufficiently unloaded at that moment. Jim Bell References Visible links 1. https://en.wikipedia.org/wiki/Qualcomm_Snapdragon 2. https://en.wikipedia.org/wiki/System_on_a_chip 3. https://en.wikipedia.org/wiki/Semiconductor 4. https://en.wikipedia.org/wiki/Qualcomm 5. https://en.wikipedia.org/wiki/Central_processing_unit 6. https://en.wikipedia.org/wiki/ARM_architecture 7. https://en.wikipedia.org/wiki/RISC_instruction_set 8. https://en.wikipedia.org/wiki/CPU_core 9. https://en.wikipedia.org/wiki/Adreno 10. https://en.wikipedia.org/wiki/Graphics_processing_unit 11. https://en.wikipedia.org/wiki/Qualcomm_Snapdragon_LTE_modem 12. https://en.wikipedia.org/wiki/Wireless_modem 13. https://en.wikipedia.org/wiki/Qualcomm_Hexagon 14. https://en.wikipedia.org/wiki/Digital_signal_processor 15. https://en.wikipedia.org/wiki/Qualcomm_Spectra 16. https://en.wikipedia.org/wiki/Image_processor 17. https://en.wikipedia.org/wiki/Global_positioning_system 18. https://en.wikipedia.org/wiki/Gesture_recognition 19. https://en.wikipedia.org/wiki/AI_accelerator 20. https://en.wikipedia.org/wiki/Android_(operating_system) 21. https://en.wikipedia.org/wiki/Windows_Phone 22. https://en.wikipedia.org/wiki/Netbook 23. https://en.wikipedia.org/wiki/Qualcomm_Snapdragon#cite_note-1 24. https://en.wikipedia.org/wiki/Wi-Fi 25. https://en.wikipedia.org/wiki/4G 26. https://datproject.org/ 27. https://gnunet.org/ 28. https://git-annex.branchable.com/ 29. https://scuttlebutt.nz/ 30. http://anarchovegas.com/ 31. mailto:jdb10987@yahoo.com 32. https://en.wikipedia.org/wiki/Single-board_computer 33. http://www.vcfed.org/forum/showthread.php?57918-Dyna-Micro-Single-Board-Computers 34. https://datasheetspdf.com/datasheet/MCM6605A.html 35. http://www.storagesearch.com/consumer-ssd.html 36. http://www.s100computers.com/Hardware Folder/SemiDisk/History/History.htm 37. https://datproject.org/ 38. https://gnunet.org/ 39. https://git-annex.branchable.com/ 40. https://scuttlebutt.nz/ 41. mailto:gmkarl@gmail.com 42. https://github.com/xloem/openrealrecord 43. https://github.com/xloem/libgame/blob/wip-1/source/stream-up.cpp 44. http://bountysource.com/ 45. https://github.com/guardianproject/haven/pull/418 46. mailto:jdb10987@yahoo.com 47. https://www.sparkfun.com/news/702 48. https://www.theglobeandmail.com/technology/gadgets-and-gear/gadgets/your-own-personal-black-box/article4300839/ 49. https://www.zdnet.com/article/fitbit-activity-data-as-evidence-in-court-wearables-serve-as-personal-black-boxes/ 50. https://www.medgadget.com/2005/08/cpod_a_personal.html 51. https://newatlas.com/australia-black-box-flight-recorder-soldiers/51267/ Hidden links: 53. https://en.wikipedia.org/wiki/Single-board_computer 54. http://www.vcfed.org/forum/showthread.php?57918-Dyna-Micro-Single-Board-Computers 55. https://datasheetspdf.com/datasheet/MCM6605A.html 56. http://www.storagesearch.com/consumer-ssd.html 57. http://www.s100computers.com/Hardware%20Folder/SemiDisk/History/History.htm