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RONJA

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Single high-brightness LED with a cheap loupe lens creates a bright narrow[1] beam that can stream DVD-quality video over neighbourhoods. A few steps aside and the narrow beam becomes invisible.
Twibright Ronja with 130-millimetre (5.1 in) diameter lenses, operating on a 1,205-metre (1,318 yd) link using visible red light, max. range 1,300 metres (1,400 yd), with HPWT-BD00-E4000 transmit LED. Installed on a rooftop, with its user, in Czech Republic.[2][3]
Three bolts preloaded with pink rubber blocks facilitate fine adjustment of the optical head direction with a gear ratio 1:300.[1] The bolt on the right side is a part of a rough adjustment mechanism which allows pointing the optical head in virtually any direction.
Artificially enhanced picture of a situation where a Ronja link stops working because of heavy fog

RONJA (Reasonable Optical Near Joint Access) is a free-space optical communication system developed in the Czech Republic by Karel Kulhavý of Twibright Labs. Released in 2001. It transmits data wirelessly using beams of light. Ronja can be used to create a 10 Mbit/s full of duplex Ethernet point-to-point link. It has been estimated that 1,000 to 2,000 links have been built worldwide.[4]

The basic configuration has a range of 1.4 km (0.87 mi). The device consists of a receiver and transmitter pipe (optical head) mounted on a sturdy adjustable holder. Two coaxial cables are used to connect the rooftop installation with a protocol translator installed in the house near a computer or switch. By doubling or tripling the transmitter pipe, the range can be extended to 1.9 km (1.2 mi).

Building instructions, blueprints, and schematics are published under the GNU Free Documentation License, with development using only free software tools. The author calls this level of freedom "User Controlled Technology".[5] Ronja is a project of Twibright Labs.

Manufacture

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The building instructions are written with an inexperienced builder in mind. Basic operations like drilling, soldering etc., are explained.[6] Several techniques – drilling templates,[7] detailed checks after soldering,[8][9][10][11] testing procedures[12][13][14] – are employed to minimize errors at critical places and help to speed up work. Printed circuit boards are downloadable ready for manufacture, with instructions for the fabhouse.[15][16] People with no previous experience with building electronics have reported on the mailing list that the device ran on the first try.

154 installations worldwide have been registered into a gallery with technical data and pictures.[2]

Range

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With the brightest variant of Lumileds HPWT-BD00-F4000 LED and 130 mm diameter cheap magnifying glass lenses, the range is 1.4 km (0.87 mi).[5][17] The dimmer but more affordable E4000 variant of HPWT-BD00 yields 1.3 kilometres (0.81 mi).[18] The speed is always 10 Mbit/s full duplex regardless of the distance.

Models

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  • Ronja Tetrapolis: Range of 1.4 km (0.87 mi), red visible light. Connect with 8P8C connector into a network card or switch.
  • Ronja 10M Metropolis: Range of 1.4 km (0.87 mi), red visible light. Connects to Attachment Unit Interface.
  • Ronja Inferno: Range of 1.25 km (0.78 mi), invisible infrared light.
  • Ronja Benchpress: A measurement device for developers for physical measurement of lens/LED combination gain and calculation of range from that
  • Ronja Lopipe: The original (discontinued) design using red visible light and a RS232 interface for a max 115 kbit/s PPP/SLIP link.[19]

Limitations

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By definition, clear visibility between the transmitter and receiver is essential. If the beam is obscured in any way, the link will stop working. Typically, problems may occur during conditions of snow or dense fog.[20][21] One device weighs 15.5 kg (34 lb)[1] and requires 70 hours of building time.[22] It requires an ability to set full duplex manually on the network card or switch to take advantage of full duplex,[23] since it doesn't support autonegotiation.[1] Must be plugged directly into PC or switch using the integral 1 metre (3 ft 3 in) Ethernet cable.[1]

Technology

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Block diagram of a full duplex RONJA system.

A complete RONJA system is made up of 2 transceivers: 2 optical transmitters and 2 optical receivers. They are assembled individually or as a combination. The complete system layout is shown in the block diagram.

Optical receiver – Preamplifier stage

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Map showing the distribution of the 153 registered installations of RONJA as of 1 October 2007. Based on data found at the official RONJA website

The usual approach in FSO (Free Space Optics) preamplifiers is to employ a transimpedance amplifier. A transimpedance amplifier is a very sensitive broadband high-speed device featuring a feedback loop. This fact means the layout is plagued with stability problems and special compensation of PIN diode capacitance must be performed, therefore this doesn't allow selection of a wide range of cheap PIN photodiodes with varying capacitances.

Ronja however uses a feedbackless design[8] where the PIN has a high working electrical resistance (100 kilohms)[8] which together with the total input capacitance (roughly 8 pF, 5 pF PIN and 3 pF[24] input MOSFET cascode) makes the device operate with a passband on a 6 dB/oct slope of low pass formed by PIN working resistance and total input capacitance.[25][26] The signal is then immediately amplified to remove the danger of contamination by signal noise, and then a compensation of the 6 dB/oct slope is done by derivator element on the programming pins[27] of an NE592 video amplifier.[28][26] A surprisingly flat characteristic is obtained. If the PIN diode is equipped with 3 kΩ working resistor to operate in flat band mode, the range is reduced to about 30% due to thermal noise from the 3 kΩ resistor.

Optical transmitter – Nebulus infrared LED driver

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The HSDL4220 infrared LED is originally unsuitable for 10 Mbit/s operation. It has a bandwidth of 9 MHz,[29] where 10 Mbit/s Manchester-modulated systems need bandwidth of around 16 MHz. Operation in a usual circuit with current drive would lead to substantial signal corruption and range reduction. Therefore, Twibright Labs developed a special driving technique consisting of driving the LED directly with 15-fold 74AC04 gate output in parallel with RF voltage applied current-unlimited directly to the LED through large capacitors.[30] As the voltage to keep the nominal LED average current (100mA) varies with temperature and component tolerances, an AC-bypassed current sense resistor is put in series with the LED. A feedback loop measures voltage on this resistor and keeps it at a preset level by varying supply voltage of the 74AC04 gates. Therefore, the nominally digital[31] 74AC04 is operating as a structured power CMOS switch completely in analog mode.

This way the LED junction is flooded and cleared of carriers as quickly as possible, basically by short circuit discharge. This pushes the speed of the LED to maximum, which makes the output optical signal fast enough so that the range/power ratio is the same as with the faster red HPWT-BD00-F4000 LED. The side effects of this brutal driving technique are: 1) the LED overshoots at the beginning of longer (5 MHz/1 MHz) impulses to about 2x brightness. This was measured to have no adverse effect on range. 2) A blocking ceramic capacitor bank backing up the 74AC04 switching array is crucial for correct operation, because charging and discharging the LED is done by short circuit. Under dimensioning this bank causes the leading and trailing edges of the optical output to grow longer.

Transceiver – Ronja Twister

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Ronja Twister is an electronic interface for free space optical datalink based on counter and shift register chips. It is a part of the Ronja design. It is effectively an optical Ethernet transceiver without the optical drive part.[32]

The original design has been superseded with Twister2 but the logic circuit remained the same.[33]

Open source hardware approach

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Soderberg, studying Ronja sociologically, writes: "Arguably, the first project that vindicated the methods and licensing schemes of free software development, applied those practices to open hardware development, and pulled off a state-of-the-art technology without any backing from universities or firms, was the Ronja project."[34]

The whole toolchain is built strictly upon free tools[35] and the source files are provided, free, under the GPL.[36] This allows anyone to enter the development, start manufacture or invest into the technology without entry costs. Such costs normally can include software licence costs, time investment into resolution of compatibility issues between proprietary applications, or costs of intellectual property licence negotiations. The decision to conceive the project this way was inspired by observed organizational efficiency of Free Software.

On Christmas 2001, Ronja became the world's first 10 Mbit/s Free Space Optics device with free sources.[37]

Examples of tools used in development:

See also

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Notes

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  1. ^ a b c d e "Ronja Tetrapolis Specification". ronja.twibright.com. Retrieved 3 June 2017.
  2. ^ a b "154 Registered Installations of Ronja". ronja.twibright.com. Retrieved 3 June 2017.
  3. ^ "[1208] ronja/installations/czech/zdar_n_sazavou". images.twibright.com. Retrieved 3 June 2017.
  4. ^ Soderberg, J. (2010). "Free Space Optics in the Czech Wireless Community: Shedding Some Light on the Role of Normativity for User-Initiated Innovations". Science, Technology, & Human Values. 36 (4): 423–450. doi:10.1177/0162243910368398. S2CID 145786449.
  5. ^ a b "Ronja – BRL-CAD". brlcad.org. Retrieved 3 June 2017.
  6. ^ "Fundamentals of manufacturing operations". ronja.twibright.com. Retrieved 3 June 2017.
  7. ^ "All Ronja Drawings". ronja.twibright.com. Retrieved 3 June 2017.
  8. ^ a b c "Building Ronja 10M Receiver". ronja.twibright.com. Retrieved 3 June 2017.
  9. ^ "Building Ronja 10M Metropolis Transmitter". ronja.twibright.com. Retrieved 3 June 2017.
  10. ^ "Building Ronja Twister2 PCB". ronja.twibright.com. Retrieved 3 June 2017.
  11. ^ "Building Ronja Nebulus". ronja.twibright.com. Retrieved 3 June 2017.
  12. ^ "Testing Ronja Tetrapolis". ronja.twibright.com. Retrieved 3 June 2017.
  13. ^ "Testing Ronja 10M Metropolis". ronja.twibright.com. Retrieved 3 June 2017.
  14. ^ "Testing Ronja Inferno". ronja.twibright.com. Retrieved 3 June 2017.
  15. ^ "Twister2 PCB". ronja.twibright.com. Retrieved 3 June 2017.
  16. ^ "Ronja: Ordering TX PCB's". ronja.twibright.com. Retrieved 3 June 2017.
  17. ^ "Evropský polytechnický institut, s.r.o. 1. soukromá vysoká škola na Moravě Kunovice POČÍTAČOVÉ SÍTĚ – PDF". docplayer.cz. Retrieved 3 June 2017.
  18. ^ "Ronja 10M Metropolis, Tetrapolis, Inferno, Rexlator distance issues". ronja.twibright.com. Retrieved 3 June 2017.
  19. ^ "Twibright Labs : Ronja". linas.org. Retrieved 3 June 2017.
  20. ^ "Download Limit Exceeded". CiteSeerX 10.1.1.963.9463. {{cite journal}}: Cite journal requires |journal= (help)
  21. ^ "Naval Applications for LiFi: The Transmitting Tool". cimsec.org. 10 August 2016. Retrieved 3 June 2017.
  22. ^ "How much does Ronja cost?". ronja.twibright.com. Retrieved 3 June 2017.
  23. ^ "Ronja Tetrapolis: Requirements (Modules, Material, Tools, Software)". ronja.twibright.com. Retrieved 3 June 2017.
  24. ^ "NXP Semiconductors: BF 908 Datasheet, page 2, table row "input capacitance at gate 1"" (PDF). nxp.com. Retrieved 3 June 2017.
  25. ^ Phanumas Khumsat, Noppadol Wattanapisit, Karel Kulhavey, "Low-Cost Laser-Based Wireless Optical Transceiver for 10-Mbps Ethernet Link", Proceedings of IEEE Region 10 Conference (TENCON), Hong Kong, China (2006) (full text), pag 2 upper left, mention about "unwanted lossy integrator".
  26. ^ a b "How does Ronja work?". ronja.twibright.com. Retrieved 3 June 2017.
  27. ^ "Philips Semiconductors RF Communications Products: NE592 Product specification, page 1 lines 6–7 of the 1st paragraph and page 8, heading "FILTER NETWORKS"" (PDF). nxp.com. Retrieved 3 June 2017.
  28. ^ Phanumas Khumsat, Noppadol Wattanapisit, Karel Kulhavey, "Low-Cost Laser-Based Wireless Optical Transceiver for 10-Mbps Ethernet Link", Proceedings of IEEE Region 10 Conference (TENCON), Hong Kong, China (2006) (full text)
  29. ^ "HSDL-4220 Datasheet" (PDF). mouser.com. Retrieved 3 June 2017.
  30. ^ "Ronja Nebulus (infrared transmitter) schematic" (PDF). twibright.com. Retrieved 3 June 2017.
  31. ^ "Fairchild: 74AC04 Datasheet" (PDF). colorado.edu. Retrieved 3 June 2017.
  32. ^ "Ronja Twister". ronja.twibright.com. Retrieved 3 June 2017.
  33. ^ "Ronja Twister2". ronja.twibright.com. Retrieved 3 June 2017.
  34. ^ Söderberg, Johan (18 June 2013). "How open hardware drives digital fabrication tools such as the 3D printer". Internet Policy Review. 2 (2). doi:10.14763/2013.2.138. hdl:10419/213966. Retrieved 3 June 2017.
  35. ^ "Software used for Ronja development". ronja.twibright.com. Retrieved 3 June 2017.
  36. ^ "All Schematics". ronja.twibright.com. Retrieved 3 June 2017.
  37. ^ "Build Your Own 10Mbit/sec Optical Data Link – Slashdot". hardware.slashdot.org. 22 December 2001. Retrieved 3 June 2017.
  38. ^ Schematic capture
  39. ^ PCB, gEDA Project

References

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