Siae Microelettronica

SIAE MICROELETTRONICA S.p.A
Private
Industry Telecommunications equipment
Networking equipment
Communications
Founded 1952 (1952)
Founder Edoardo Mascetti
Headquarters Cologno Monzese (Milan) Italy
Area served
Worldwide
Products Wireless backhaul and Fronthaul
Number of employees
+1500 (2016)
Website www.siaemic.com

SIAE MICROELETTRONICA is an Italian multinational corporation and a global supplier of telecom network equipments. It provides wireless backhaul and fronthaul solutions that comprise microwave and millimeter wave radio systems, along with fiber optics transmission systems provided by its subsidiary SM Optics.

Company products are deployed in more than 90 countries worldwide. The company is headquartered in Milan, Italy, with 26 regional offices around the globe.[1]

Corporate history

1952–1970s: Origins and initial growth

Edoardo Mascetti, after graduating in 1949 in Electrical Engineering at the Polytechnic University of Milan and working as electronic designer for Siemens, founded his own company and named it SIAE, acronym for SocietΓ  Italiana Apparecchiature Elettroniche[2] The company manufactured measurement systems such as electro-mechanical testers, analog oscilloscopes, telephone system analyzers and signal generators. SIAE's sales volume in 1955 was 6.224.000 Italian lire and doubled by the end of 1957.

A 431A-model oscilloscope[3] by SIAE was also part of the synthesizer in the Studio di fonologia musicale di Radio Milano(RAI) until its dismissal on 1983 and is currently on permanent display with the original study equipment at the Musical Instrument museum hosted at the Castello Sforzesco, Milan.[4]

SIAE Oscilloscope 431A (introduced in 1963) used for the synthesizer in the Studio di fonologia musicale di Radio Milano
Company's headquarters in Cologno Monzese, approx. 1966

A few years after founding SIAE, Edoardo Mascetti co-founded in 1958 Microelettronica S.p.A., a company whose business was the design of telecommunication equipment for radio and landline systems and which was initially located in a basement in Milan. In 1963, the two complementary companies were merged into SIAE MICROELETTRONICA S.p.A. and the headquarters was moved to the nearby town of Cologno Monzese, where a larger area was available to accommodate the new offices and manufacturing plant.[2]

The new company counted less than 50 employees and focused its business on telecommunication systems, which were rising thanks to the capillary diffusion of telephone systems in Italy. Analog multiplexing systems for telephone providers constituted the company's principal product; nonetheless, in 1963, the company began an active collaboration with ENEL, italian provider of electric power, in order to create a supervision system for the national distribution network, whose successful outcome later fostered similar activities in northern Europe and specifically in Norway.

By the mid '60s, the company began actively promoting its products by advertising in technical journals as natural consequence of a growing business, thanks to its first large-scale commercialized radio transceiver: the 3-channel 3-B3 and later the RT450 (1966), capable of aggregating 48 channels into UHF band. The RT450 equipment was also certified by it:Telettra under the commercial name H450 as fallback link for its high-capacity solutions. Power-line communication systems were also manufactured by the company in those years along with the first fixed and mobile communication terminals in VHF band (1972) for vehicular communications (precurring modern mobile phones) and anti burglar alarm systems.

2.3GHz modulator for RT12 transceivers, exploiting microstrip technology on PTFE for connections and electromagnetic coupling for filtering and splitting purposes (1978).

By 1973, a whole new internal division was created for the design of television broadcasting equipments (repeaters and transmitters) whose main customer was the national television company RAI. The first television products were based on thermo-ionic tubes though the improvement of solid state technologies soon replaced vacuum tubes. Similar improvements in printed board manufacturing made microstrip circuits a viable solution for increasingly-high microwave frequencies and in 1978 the RT12 radio equipment boasted the first direct-conversion 2.3 GHz synthesized modulator and could aggregate 120 telephone channels. In these years, the company manufactured the historical link to connect the Milan and Rome branches of the Corriere della Sera newspaper.[5]

The employees were about a hundred though the company still remained a family-run business lead by the founder and a tight board of managers through the '70s. Computer-aided design of electronic circuits was approached and exploited to improve yield and reduce the design time especially for the critical high-frequency sections.[6]

1980s-2000s: Digital and worldwide company

RT20 digital radio transceiver, carrying up to 30 telephone channels and operating at 0.9GHz of carrier frequency (1981).

The early '80s witnessed two intertwined aspects which boosted the activities: the digital revolution reached commercial radio links and the RT20 thus leveraged 4-QAM modulation in order to provide low-capacity links while the increased globalization opened up international markets and the company business expanded to Norway, Great Britain and gradually to Europe. A quality control system was soon implemented to meet and certify the improved production standards.

In partnership with then it:Telettra, the Company developed the multi channel radio network covering the national extents, named RIAM, for the national electric company, Enel. The radio equipments were governed by a microprocessor, in the wake of the widespread usage of these new components which offered a huge range of new possibilities for coordinating radio components when compared to traditional dedicated circuits.[2]

With the increased demand for traffic, higher frequencies were needed and in the second half of the 80's the company commercialized its 18 GHz radio transceiver with a capacity up to 2Mbit/s, based on specifications of Enel. A 13 GHz equipment with 4Mbit/s was instead first provided to the Mercury operator in the UK.

Thin film manufacturing techniques for printed circuit boards were adopted during the 80s by the company for its microwave products beyond 10 GHz with ad-hoc equipments and production lines (yellow room) and soon upgraded to chip-and-wire technologies in white rooms (clean room). Documents show the RT28 transceiver remained in service until 2008 in the Italian Aosta Valley.[7]

18GHz RT28 split-mount transceiver, capable of up to 2Mbit/s communication (1986)

In 1986 the Company introduced the "split-mount" configuration, where an indoor unit (IDU) is connected to an outdoor unit ODU. The IDU provides the network interfaces and carries out the baseband tasks while communicates with the ODU, usually by means of an intermediate frequency, which is tasked of radio frequency up/down conversion and is connected to the antenna. The split-mount configuration is still currently in use in several modern radio products and the boost in sales at that time was recognized in the 1988 edition of Major Companies of Europe.[8]

In the early '90s the diffusion of data services and SDH required higher capacities to be transported and in 1992 the Company provided its HS13 SDH equipment to the SIP telephone company (later become Telecom Italia) entering thus the market of high-capacity microwave radio links and introducing enhanced techniques to counteract non-idealities in the communication channel and the transceiver hardware.[9][10]

Simultaneously, subsidiaries were opened in Latin America and Far East. To meet international standards for control and supervision of the increasingly complex networks of radio links, the Company developed its own Network management system providing a unified interface for all its products. One of the first versions of monitoring software was still in use as of 2012 for a it:TETRA network.[11]

In the meantime, the production of television transmitters and repeaters was halted in order to focus the activities towards the core business of backhauling radio links. The increased volume of chip and wire components fostered the introduction of improved Cleanrooms, upgraded to the 10'000 class. The Company further evolved internally to expand its business and offer the services surrounding the mere provision of hardware, such as network planning, assistance, installation and contributed to the activities of international standardization bodies.[12]

In the late 90s the Company commercialized a family of products whose design was dedicated to the booming market of GSM cellular mobile communications. In 1999, the offer was expanded to support high-capacity SDH traffic and a number of multiplexing equipments were developed as well to address the increased complexity and demanded flexibility of network configurations and interfaces.

Present day

The Twenty-first century was inaugurated by the first direct collaboration and commercial relationships with China which in 2014 lead to a dedicated subsidiary, Siae Telecommunications Shenzhen Limited.[13] The first european subsidiary opened in 2002 in Paris while the first non-european branch initiated activities in 2006 in Bangkok. The production and assembly processes began transitioning from manual to automatic SMT placement equipment in the early 2000s to cope with a volume of 15'000 radios/year while the yearly sales in 2002 increased by 25.8%.[14]

In partnership with Cisco, the Company developed algorithms and dedicated implementations for adaptive bandwidth and adaptive modulation schemes, which allow to react to impaired communication conditions (such as rain) gracefully reducing the link throughput instead of temporarily suspending the communication (out of service). Such solutions, extensively relied upon for network planning, are currently standard in most modern point-to-point radio links for backhauling.[15]

In the wake of the global migration from circuit switching towards IP packet networks, the Company developed Full IP equipments in split-mount and full-outdoor versions and also dual native radios, supporting both TDM and Ethernet modes, whose popularity positively affected company's sales volume. To meet the ever-increasing demand for higher throughput without need for additional bandwidth, which is licensed at a price in most dedicated bands, frequency reuse dominated subsequent industrial developments and the adoption of dual-polarization techniques was commercially proposed in 2007, when the company and Vodafone (Omnitel by that time) presented the paper "2xSTM1 frequency reuse system with XPIC" at the European Conference on Fixed Wireless Network Technologies 2007 in Paris.[16]

Thanks to Full IP and XPIC equipment sales, the yearly production of radios hit 70'000 in 2011 while the sales income topped 180 million Euro [17] and by the end of 2012 the number of people employed by the company exceeded 1000 over the 25 world branches, about 700 of which located in the Cologno Monzese headquarters.[18]

The juridical literature reports of a litigation initiated in 2006 by NEC Corporation against SIAE Microelettronica over alleged infringement of several former's patents in the courts of Milan and Munich. The case was closed in 2010 with a bilateral agreement to withdraw all infringement, nullity and opposition actions pending worldwide.[19][20][21]

Although not directly involved in antenna manufacturing, the Company and Polytechnic University of Milan patented in 2011 a dielectric antenna for mm-wave communications based on a novel design aimed at reducing the overall size, whose application targeted small form factor radio equipments.[22] The visual impact of transceivers began in those years to earn importance for the deployment of urban links, where the existing environment should be affected as little as possible by access stations and backhauling transceivers with their antennas.

In 2013 the company entered the millimeter-wave market with its full-outdoor transceivers in E-Band. In 2014, the product portfolio included also V band radios for small cell backhaul and NLOS solutions for urban communications which may benefit from exploiting reflections on buildings in order to increase coverage. A new network monitoring software was also released in 2014 to offer enhanced features to network operators for managing and evaluating aggregated performances, which are gaining more and more relevance as key figures in the assessment of traffic bottlenecks and overall behavior of a complex network.[23][24]

In 2014 the labs for the management system for terrestrial networks and two families of equipment for fiber optic telecommunicationsβ€”OMSN (Optical Multi-Service Node) and TSS (Transport Service Switch)β€” were transferred from Alcatel Lucent (now Nokia) to a new dedicated company, SM Optics, a subsidiary of SIAE Microelettronica.[25][26][27][28][29][30]

From 2014 to 2016, through its entirely owned company "Twist-off" in Padua (Italy), Siae Microelettronica was active in researching applications of Orbital Angular Momentum of light (OAM) communications applied to long-distance links.[31][32][33][34] Field tests of the principles were also published [35][36][37] and filed under an industrial patent [38] based on the twisted parabola.[39] As a means to increase capacity and frequency reuse orbital angular momentum multiplexing was also compared to traditional MIMO spatial multiplexing techniques in terms of antenna size/spacing/occupation and achievable performance, which resulted in a critical assessment showing that both have equal performances.[40] Near field properties of OAM beams at microwaves have also been investigated[41][42][43] resulting in valid theoretical and practical demonstrations to lay the ground for short-range secure communications with application to contactless payments and transactions, filed under a dedicated patent.[44]

The company continues its long standing cooperation strategy with research institutions and in 2015 it joined the Laurea Magistrale Plus program,[45] promoted by University of Pavia for Master's degree achieved with an extended and close participation in existing companies' activities.[46]

In 2016 the company presented, at the Mobile World Congress, Layer-3 VPN services over microwave radio links using SM-OS, based on Software-defined networking (SDN).[47][48]

In 2016, an internal team of researchers coauthored the "Receiver", "Modem" and "Antenna" chapters in a comprehensive book describing electronic design of transceiver frontends for backhauling.[49]

Logos

References

  1. ↑ SIAE MICROELETTRONICA. "Worldwide Subsidiaries". www.siaemic.com. Retrieved 2017-01-05.
  2. 1 2 3 Cantoni, Virginio; Falciasecca, Gabriele; Pelosi, Giuseppe (2011). Storia delle Telecomunicazioni. Firenze: Firenze University Press. p. 674. ISBN 978-88-6453-243-1.
  3. ↑ http://fonologia.lim.di.unimi.it/strumenti_scheda.php?id=47
  4. ↑ https://strumentimusicali.milanocastello.it/it/content/studio-di-fonologia-della-rai-di-milano
  5. ↑ Manzoni, Franco (2004-06-02). "Ingegnere e Partigiano, pioniere dell'elettronica". Corriere della Sera (in Italian).
  6. ↑ IEEE Microwave Theory and Techniques (1978-01-01). Digest: 1978 IEEE MTT-S International Microwave Symposium. Institute of Electrical and Electronics Engineers,. p. 88.
  7. ↑ https://appweb.regione.vda.it/dbweb/bandigara/bandigar.nsf/(vediTutti)/8D8D6BF7C43F41ACC125753700499C07/$FILE/Capitolato_appalto_ponti_radio_2008.pdf?openelement
  8. ↑ Graham; Whiteside; Blackburn (1988). Major Companies of Europe. Graham & Trotman. p. 402.
  9. ↑ Fourth European Conference on "Radio Relay Systems". Institution of Electrical Engineers. 1993. p. 238.
  10. ↑ Baccarini, L.; Biscevic, G.; Chiesa, F.; Miletic, A. (1993-10-01). "Error-correction techniques and adaptive linearization in SDH radio". 1993 Fourth European Conference on Radio Relay Systems: 238–243.
  11. ↑ http://www.comune.torino.it/vigiliurbani/poliziamunicipale/struttura/comando/appalti/pdf/capitolato_servizio_progettazione_radio13.pdf
  12. ↑ Report on the Activities of the International Telecommunication Union in ... The Union. 1994-01-01. p. 73.
  13. ↑ "China Subsidiaries". www.siaemic.com. Retrieved 2017-01-05.
  14. ↑ Vergnano, Franco (2003-10-25). "Aziende di famiglia con una marcia un piΓΉ". Il Sole 24 Ore.
  15. ↑ "Microwave Adaptive Bandwidth Feature: Make Better Use of Available Bandwidth". Cisco. Retrieved 2017-01-05.
  16. ↑ Rossi; Calia; Nava; Salvaneschi; Agabio; Cornaglia; Ratia (2007). "2xSTM-1 Frequency Reuse System with XPIC" (PDF). Proc. 8th Eur. Conf. Fixed Wireless Netw. Technol. (ECRR’07).
  17. ↑ Bordeaux, reportaziende.it - La Stanza. "SIAE-MICROELETTRONICA - S.P.A. (p.iva 00779180157) - MILANO (MI) su reportaziende.it". www.reportaziende.it. Retrieved 2017-01-05.
  18. ↑ Bordeaux, reportaziende.it - La Stanza. "SIAE-MICROELETTRONICA - S.P.A. (p.iva 00779180157) - MILANO (MI) su reportaziende.it". www.reportaziende.it. Retrieved 2017-01-05.
  19. ↑ "NEC files patent lawsuit vs. SIAE Microelettronica". archive.eetasia.com. Retrieved 2017-01-05.
  20. ↑ Laura. "NEC/SIAE MICROELETTRONICA LITIGATION SETTLEMENT". www.siaemic.com. Retrieved 2017-01-05.
  21. ↑ Gasnier, Arnaud (2008-01-01). The Patenting Paradox: A Game-based Approach to Patent Management. Eburon Uitgeverij B.V. p. 58. ISBN 9789059722309.
  22. ↑ MI2011A002141, Magistroni, Claudio; Oriano Cattaneo & Michele D'Amico et al., "Antenna dielettrica ottimizzata per trasmissioni a frequenze millimetriche", published 2011
  23. ↑ "The Role of KPIs in Network Management". Techopedia.com. Retrieved 2017-01-05.
  24. ↑ Mishra, Ajay R. (2004-05-21). Fundamentals of Cellular Network Planning and Optimisation: 2G/2.5G/3G... Evolution to 4G. John Wiley & Sons. p. 48. ISBN 9780470862674.
  25. ↑ "Alcatel-Lucent concludes agreement with Italy’s SM Optics for transfer of specific optical research and development activities". Nokia Networks. 2014-11-27. Retrieved 2017-01-05.
  26. ↑ "Alcatel-Lucent transfers optics R&D to Italy's SM Optics". www.lightwaveonline.com. Retrieved 2017-01-05.
  27. ↑ "Alcatel Lucent cede un altro ramo". Il Sole 24 ORE. Retrieved 2017-01-05.
  28. ↑ "Il governo festeggia le aziende salvate, ma a Natale restano 153 crisi aperte". Repubblica.it. 2014-12-19. Retrieved 2017-01-05.
  29. ↑ "Alcatel-Lucent, 300 dipendenti passano a Siae". www.corrierecomunicazioni.it. Retrieved 2017-01-05.
  30. ↑ "ultimaora - flash news 24 Corriere della Sera". www.corriere.it. Retrieved 2017-01-05.
  31. ↑ Spinello, Fabio; Parisi, Giuseppe; Tamburini, Fabrizio; Romanato, Filippo; Mari, Elettra (2015). Laguerre-Gauss (LG) p-modes generation in the radio frequency domain. International Conference on Orbital Angular Momentum (ICOAM). New York (NY), USA.
  32. ↑ Parisi, Giuseppe; Mari, Elettra; Spinello, Fabio; Tamburini, Fabrizio; Romanato, Fabrizio (2015). Tailoring optical beam shape by superposing consecutive OAM modes. International Conference on Orbital Angular Momentum (ICOAM). New York (NY), USA.
  33. ↑ Spinello, Fabio; Parisi, Giuseppe; Tamburini, Fabrizio; Massaro, Giovanni; Someda, Carlo; Oldoni, Matteo; Ravanelli, Roberto; Romanato, Filippo; Mari, Elettra (2015). "High-order vortex beams generation in the radio-frequency domain". IEEE Antennas and Wireless Communication Letters.
  34. ↑ Parisi, Giuseppe; Mari, Elettra; Spinello, Fabio; Romanato, Filippo; Tamburini, Fabrizio (2014). "Manipulating intensity and phase distribution of composite Laguerre-Gaussian beams". Optics Express. 22: 17135–46. PMID 25090528. doi:10.1364/oe.22.017135.
  35. ↑ Tamburini, Fabrizio; Mari, Elettra; Parisi, Giuseppe; Spinello, Fabio; Oldoni, Matteo; Ravanelli, Roberto; Coassini, Piero; Someda, Carlo; Thide, Bo; Romanato, Filippo (2015). "Tripling the capacity of a point-to-point radio link by using electromagnetic vortices". Radio Science. 50: 501–508. doi:10.1002/2015RS005662.
  36. ↑ Spinello, Fabio; Mari, Elettra; Parisi, Giuseppe; Tamburini, Fabrizio; Romanato, Filippo; Someda, Carlo (2014). Experimental generation and measurement of Orbital Angular Momentum (OAM) radio waves. Riunione Nazionale di Elettromagnetismo. Padua, Italy. }}
  37. ↑ Spinello, Fabio; Someda, Carlo; Ravanelli, Roberto; Mari, Elettra; Parisi, Giuseppe; Romanato, Filippo; Coassini, Piero; Oldoni, Matteo (2016). "Radio channel multiplexing with superpositions of opposite-sign OAM modes". International Journal of Electronics and Radio Communications. 70: 990–997. doi:10.1016/j.aeue.2016.03.017.
  38. ↑ WO2014170869 A1, Tamburini, Fabrizio; Bo ThidΓ¨ & Filippo Romanato et al., "Method for generating microwave or rf electromagnetic wave beams with non-zero orbital angular momentum and with intensity distribution concentrated in a limited angular region", published 23 Oct. 2014
  39. ↑ http://rexresearch.com/tamburini/tamburini.htm
  40. ↑ Oldoni, Matteo; Spinello, Fabio; Mari, Elettra; Parisi, Giuseppe; Someda, Carlo Giacomo; Tamburini, Fabrizio; Romanato, Filippo; Ravanelli, Roberto Antonio; Coassini, Piero; Thide, Bo (2015). "Space-Division Demultiplexing in Orbital-Angular-Momentum-Based MIMO Radio Systems". IEEE Transactions on Antennas and Propagation. 63 (10): 4582–4587. Bibcode:2015ITAP...63.4582O. doi:10.1109/TAP.2015.2456953.
  41. ↑ Mari, Elettra; Spinello, Fabio; Oldoni, Matteo; Ravanelli, Roberto; Romanato, Filippo; Parisi, Giuseppe (2014). "Near-Field Experimental Verification of Separation of OAM Channels". IEEE Antennas and Propagation Letters.
  42. ↑ Mari, Elettra; Spinello, Fabio; Tamburini, Fabrizio; Romanato, Filippo; Oldoni, Matteo (2015). Secure short range communications based on OAM. International Conference on Orbital Angular Momentum (ICOAM). New York (NY), USA.
  43. ↑ Vallone, Giuseppe; Parisi, Giuseppe; Spinello, Fabio; Mari, Elettra; Villoresi, Paolo (2016). "General theorem on the divergence of vortex beams". Physical Review A. 94. doi:10.1103/PhysRevA.94.023802.
  44. ↑ US 20160292472, Tamburini, Fabrizio; Filippo Romanato & Elettra Mari et al., "Metodo di comunicazione sicura a corto raggio"
  45. ↑ "news.unipv – LM+". news.unipv. Retrieved 2017-01-09.
  46. ↑ "A Pavia l’impresa entra in ateneo". www.scuola24.ilsole24ore.com. Retrieved 2017-01-09.
  47. ↑ http://www.ansa.it/sito/notizie/economia/business_wire/2016-02-22_1221378985.html
  48. ↑ "SIAE MICROELETTRONICA and Aricent Showcasing "New IP" over SM-OS Based Microwave Radio Portfolio". Aricent. 2016-02-23. Retrieved 2017-01-05.
  49. ↑ Camarchia, Vittorio; Quaglia, Roberto; Pirola, Marco (2016). Electronics for Microwave Backhaul. Artech House. ISBN 978-1-63081-015-3.
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