R&M – R&M Opens New Fiber Optic Plant in India

R&M

High demand for fiber optic cabling components requires additional capacities.

 

R&M, the globally active Swiss developer and provider of high-end infrastructure solutions for data and communications networks, opened a new fiber optic plant in India in mid-May. The entire infrastructure was relocated to Bagaluru, in the north of Bangalore. Investments were also made in new production lines and production capacity was further increased. Bagaluru is R&M’s largest site worldwide for the manufacture of fiber optic cabling components.

Laurent Amestoy, EVP Asia Pacific

 

«Demand for fiber optic connectivity solutions from R&M is increasing in India and Asia in general. The driving forces are broadband supply, 5G, and data centers. That’s why we’re building up additional manufacturing capacities here. The fiber optic plant plays a key role in our regional growth strategy and strengthens our position as a top-quality vendor of connectivity infrastructure solutions,» explains Laurent Amestoy, Executive Vice President of R&M APAC.

 

Michel Riva, CEO

«With this investment, we are reaffirming R&M’s commitment to a long-term involvement in the growth market of India. The new plant will also assume a global function. As the largest production site, it provides flexible and responsive resources for our supply chain. This makes us more competitive and also ready for a new upswing in western markets,» says R&M CEO Michel Riva.

 

Proximity to the international airport

Markus Stieger, COO

 

«Bagaluru provides the ideal premises in the dynamic industrial agglomeration of Bangalore. The plant is located just ten kilometers from the international airport. Spread over three floors, the new building offers flexible expansion options and 400-500 modern workplaces. Our production operation works in accordance with the high Swiss quality standards that R&M represents worldwide. Due to demand, we are already planning two- and three-shift operations,» says Markus Stieger, COO of R&M.

 

R&M has had its own production facilities in India since 2014. Initially, the focus was on assembling fiber optic patch cords for the global market. In 2018, R&M opened a plant with 200 workplaces in Jakkur near Bangalore. Demand on site increased rapidly with the broadband rollout and rapid data center growth. Today, R&M supplies India’s entire telecom industry as well as metro and smart city projects with a comprehensive fiber optic portfolio. In addition to infrastructure solutions for FTTx networks, R&M India also offers the development of dedicated cabling solutions for enterprises and data centers. Since 2023, R&M has been very successful with fiber optic connectivity solutions for the base stations of the new 5G networks in India.

R&M India promotes sustainability in several ESG areas. The plant in India is certified in accordance with international standards for occupational safety, quality, and environmental management. Employees present their questions and statements to managers in regular open-door meetings. One example of how the volume of waste is being reduced is that the use of disposable plastic bottles has been discontinued. Regular local charity initiatives are also part of the commitment, such as providing children with school bags and textbooks so that they can take part in lessons. A long-term afforestation project in Errabadu is helping to provide livelihoods for Indian farmers and contributing to CO2 compensation.

 

Link to the Reforest program: https://www.ecomatcher.com/forest-map/?fid=775

SourceR&M

EMR Analysis

More information on R&M: See the full profile on EMR Executive Services

More information on Michel Riva (Chief Executive Officer, R&M): See the full profile on EMR Executive Services

More information on Markus Stieger-Bircher (Chief Operating Officer and Sustainability Officer, R&M): See the full profile on EMR Executive Services

More information on Laurent Amestoy (Executive Vice President APAC, R&M): See the full profile on EMR Executive Services

 

 

 

 

EMR Additional Notes: 

  • Optical Cable:
    • An optical cable transfers audio digitally, but instead of copper wire, light is used. This is a variation of fiber optics, which is used in a variety of applications.
    • The biggest difference between Optical Cables and HDMI is that HDMI can pass higher-resolution audio, including the formats found on Blu-ray: Dolby TrueHD and DTS HD Master Audio. These formats can’t get transmitted across optical. In terms of simplicity, HDMI also passes video signals.

 

  • Types of Network Cabling:
    • Coaxial Cable:
      • Coaxial cables or coax, have a single copper conductor at the center, while a plastic layer provides insulation between the center conductor and braided metal shield. The metal shield blocks outside interference from fluorescent lights, motors, and other computers.
    • Twisted Pair:
      • Twisted pair uses copper wires that are, as the name suggests, twisted together in pairs. The twist effect of each pair in the cables ensures any interference presented or picked up on one cable is canceled by the cable’s partner that twists around the initial cable. Twisting the two wires also reduces the electromagnetic radiation emitted by the circuit.
        • Shielded Twisted Pair (STP) Cable:
          • In STP, copper wires are first covered by plastic insulation. A metal shield, which consists of metal foil or braid, surrounds the bundle of insulated pairs. Where electromagnetic radiation is a serious issue, each pair of wires may be individually shielded in addition to the outer shield. This is known as foil twisted pair (FTP).
        • Unshielded Twisted Pair (UTP) Cable:
          • UTP cables typically contain four pairs of copper wires, with each pair containing two wires twisted together. These pairs are covered by plastic insulation. They do not have any shielding and just have an outer jacket.
          • Most categories of twisted-pair cables are available as UTP. But some newer categories are also available in combinations of shielded, foil shielded and unshielded.
    • Fiber Optic Cable:
      • Fiber optic cables consist of a thin optical fiber surrounded by cladding. Cladding is made from glass that is less pure than the core and has a lower refractive index than the core. The difference in refractive indices causes light to be reflected at the boundary. Additional layers, such as the buffer layer and jacket layer, surround the cladding to add strength and protect the cable against damage.
      • Data rates have increased throughout the network, and in some cases, fiber optics is the only option. While Cat8 twisted-pair cables can carry up to 40 Gbps of data, fiber supports data rates up to 400 Gbps.
      • Fiber has a low error rate. Network data is encoded in a light beam. Unlike with twisted-pair cables, the light beam neither generates nor is affected by electronic interference. Additionally, multiple frequency data streams can be multiplexed over a single fiber to increase the total data rate.

 

  • FTTx:
    • Fiber to the Home (FTTH), Fiber to the Building (FTTB), Fiber to the Premises (FTTP) and Fiber to the Curb (FTTC), termed as FTTx are various technology and deployment options developed to enable reach of fiber as close to the user location as possible to provide high speed data and voice services.
    • Fiber to the home (FTTH) is the delivery of a communications signal over optical fiber from the operator’s switching equipment all the way to a home or business, thereby replacing existing copper infrastructure such as telephone wires and coaxial cable.
    • FTTP and FTTH are two different abbreviations for the same thing. FTTP stands for ‘fibre to the premises’ and FTTH stands for ‘fibre to the home’. … Unlike FTTC, FTTP broadband is delivered via fibre-optic cables not only as far as the cabinet, but across the entire span to your home or business.
    • Fiber-optic cables are less susceptible to glitches than traditional copper wires and can withstand the shock and vibration from inclement weather. FTTH is considered “future proof” and offers the flexibility to deliver additional services in the years to come.

 

 

  • Key Differences Between Copper Cable and Fiber Optics:
    • Data transmission speed of a fiber cable is comparatively more than that of copper cable. Copper cables are nearly 31% slower in data transmission than fiber cable.
    • A copper cable transmits the data through it in the form of electrical pulse i.e., due to the movement of electrons. As against in a fiber optics, the data transmission is the result of movement of photons thus it transmits in the form of light pulses.
    • The bandwidth provided by a copper cable is less than that of the fiber optics. Thus, a copper cabling meets the industry standards and provides a performance of up to 10 Gbps.  However, a fiber optics due to its large bandwidth possess better performance of up to 60 Tbps and above.
    • The energy consumed by a copper cable during its operation is somewhat greater than 10W but on the other side, fiber optics consumes less energy i.e., around 2W per user.
    • The lifespan of a copper wire is approximately 5 years as it gets easily affected by temperature variations and other environmental factors. However, fiber optics possess a lifespan of 30 to 50 years.
    • As fiber optics are difficult to be tapped as compared to copper cables thus proves advantageous from the security point of view. Due to this reason fiber optics are widely used for data transmission at present time.
    • A fiber optics allows transmission of data at a much faster rate as compared to copper cable.
    • The installation and maintenance cost of a fiber cable is more than copper cable.

 

  • Broadband Connectivity:
    • Broadband refers to various high-capacity transmission technologies that transmit data, voice, and video across long distances and at high speeds.
    • Broadband refers to telecommunications in which a wide band of frequencies is available to transmit information. Because a wide band of frequencies is available, information can be multiplexed and sent on many different frequencies or channels within the band concurrently. Multiplexing enables more information to be transmitted in a given time, much as more lanes on a highway support more cars.

 

  • 4G, 5G and 6G: 5G is the 5th generation mobile network. It is a new global wireless standard after 1G, 2G, 3G, and 4G networks.
    • 5G enables a new kind of network that is designed to connect virtually everyone and everything together including machines, objects, and devices.
      • First generation – 1G
        1980s: 1G delivered analog voice.
      • Second generation – 2G
        Early 1990s: 2G introduced digital voice (e.g. CDMA- Code Division Multiple Access).
      • Third generation – 3G
        Early 2000s: 3G brought mobile data (e.g. CDMA2000).
      • Fourth generation – 4G LTE
        2010s: 4G LTE ushered in the era of mobile broadband.
    • 5G has started hitting the market end of 2018 and will continue to expand worldwide.
    • Beyond speed improvement, the technology is expected to unleash a massive 5G IoT (Internet of Things) ecosystem where networks can serve comm
    • 5G speed tops out at 10 gigabits per second (Gbps).
      • 5G is 10 to x100 faster than what you can get with 4G.
    • The main evolution compared with today’s 4G and 4.5G (aka LTE advanced, LTE-A, LTE+ or 4G+) is that, beyond data speed improvements, new IoT and critical communication use cases will require a new level of improved performance.
      • For example, low latency provides real-time interactivity for services using the cloud: this is key to the success of self-driving cars, for example.
      • 5G vs 4G also means at least x100 devices connected. 5G must be able to support 1 million devices for 0.386 square miles or 1 km2.
      • Also, low power consumption is what will allow connected objects to operate for months or years without the need for human assistance.
      • Unlike current IoT services that make performance trade-offs to get the best from current wireless technologies (3G, 4G, Wi-Fi, Bluetooth, Zigbee, etc.), 5G networks will be designed to bring the level of performance needed for massive IoT.
    • 6G (sixth-generation wireless) is the successor to 5G cellular technology. 6G networks will be able to use higher frequencies than 5G networks and provide substantially higher capacity and much lower latency. One of the goals of the 6G internet is to support one microsecond latency communications. This is 1,000 times faster — or 1/1000th the latency — than one millisecond throughput.
      • The 6G technology market is expected to facilitate large improvements in the areas of imaging, presence technology and location awareness. Working in conjunction with artificial intelligence (AI), the 6G computational infrastructure will be able to identify the best place for computing to occur; this includes decisions about data storage, processing and sharing.
      • It is important to note that 6G is not yet a functioning technology. While some vendors are investing in the next-generation wireless standard, industry specifications for 6G-enabled network products remain years away. 6G internet is expected to launch commercially in 2030.

 

  • Data Centers:
    • A data center is a facility that centralizes an organization’s shared IT operations and equipment for the purposes of storing, processing, and disseminating data and applications. Because they house an organization’s most critical and proprietary assets, data centers are vital to the continuity of daily operations.
  • Hyperscale Data Centers:
    • The clue is in the name: hyperscale data centers are massive facilities built by companies with vast data processing and storage needs. These firms may derive their income directly from the applications or websites the equipment supports, or sell technology management services to third parties.

 

  • ESG (Environmental, Social and Governance):
    • Refers to the three key factors when measuring the sustainability and ethical impact of an investment in a business or company. Most socially responsible investors check companies out using ESG criteria to screen investments.
    • ESG metrics are not commonly part of mandatory financial reporting, though companies are increasingly making disclosures in their annual report or in a standalone sustainability report.
    • There is not a standardized approach to the calculation or presentation of different ESG metrics.
      • Environmental: Conservation of the natural world
        • Climate change and carbon emissions
        • Air and water pollution
        • Biodiversity
        • Deforestation
        • Energy efficiency
        • Waste management
        • Water scarcity
      • Social: Consideration of people & relationships
        • Customer satisfaction
        • Data protection and privacy
        • Gender and diversity
        • Employee engagement
        • Community relations
        • Human rights
        • Labor standards
      • Governance: Standards for running a company
        • Board composition
        • Audit committee structure
        • Bribery and corruption
        • Executive compensation
        • Lobbying
        • Political contributions
        • Whistleblower schemes

        •  
    • Criteria are of increasing interest to companies, their investors and other stakeholders. With growing concern about he ethical status of quoted companies, these standards are the central factors that measure the ethical impact and sustainability of investment in a company.
    • Consequently, ESG analysis considers how companies serve society and how this impacts their current and future performance.
  • CSR (Corporate Social Responsibility):
    • Framework or business model that helps a company be socially accountable to itself, its stakeholders, and the public.
    • The purpose of CSR is to give back to the community, take part in philanthropic causes, and provide positive social value. Businesses are increasingly turning to CSR to make a difference and build a positive brand around their company.
    • CSR tends to target opinion formers – politicians, pressure groups, media. Sustainability targets here the whole value chain – from suppliers to operations to partners to end-consumers.
  • CSR vs. ESG:
    • CSR is a company’s framework of sustainability plans and responsible cultural influence, whereas ESG is the assessable outcome concerning a company’s overall sustainability performance.
    • The major difference between them is that CSR is a business model used by individual companies, while ESG is a criteria that investors use to assess a company and determine if they are worth investing in.

 

  • Carbon Dioxide (CO2):
    • Primary greenhouse gas emitted through human activities. Carbon dioxide enters the atmosphere through burning fossil fuels (coal, natural gas, and oil), solid waste, trees and other biological materials, and also as a result of certain chemical reactions (e.g., manufacture of cement). Carbon dioxide is removed from the atmosphere (or “sequestered”) when it is absorbed by plants as part of the biological carbon cycle.
  • Biogenic Carbon Dioxide (CO2):
    • Carbon Dioxide released as a result of the combustion or decomposition of organic material, that is biomass and its derivatives. Examples include carbon dioxide released during the combustion of wood and biogas generated by decomposition.
    • Biogenic Carbon Dioxide (CO2) and Carbon Dioxide (CO2) are the same. Scientists differentiate between biogenic carbon (that which is absorbed, stored and emitted by organic matter like soil, trees, plants and grasses) and non-biogenic carbon (that found in all other sources, most notably in fossil fuels like oil, coal and gas).
  • Carbon Capture and Storage (CCS):
    • CCS involves the capture of carbon dioxide (CO2) emissions from industrial processes, such as steel and cement production, or from the burning of fossil fuels in power generation. This carbon is then transported from where it was produced, via ship or in a pipeline, and stored deep underground in geological formations.
    • CCS projects typically target 90 percent efficiency, meaning that 90 percent of the carbon dioxide from the power plant will be captured and stored.
  • Decarbonization:
    • Reduction of carbon dioxide emissions through the use of low carbon power sources, achieving a lower output of greenhouse gasses into the atmosphere.
  • Carbon Footprint:
    • There is no universally agreed definition of what a carbon footprint is. A carbon footprint is generally understood to be the total amount of greenhouse gas (GHG) emissions that are directly or indirectly caused by an individual, organization, product, or service. These emissions are typically measured in tonnes of carbon dioxide equivalent (CO2e).
    • In 2009, the Greenhouse Gas Protocol (GHG Protocol) published a standard for calculating and reporting corporate carbon footprints. This standard is widely accepted by businesses and other organizations around the world. The GHG Protocol defines a carbon footprint as “the total set of greenhouse gas emissions caused by an organization, directly and indirectly, through its own operations and the value chain.”
  • Carbon Credits or Carbon Offsets:
    • Permits that allow the owner to emit a certain amount of carbon dioxide or other greenhouse gases. One credit permits the emission of one ton of carbon dioxide or the equivalent in other greenhouse gases.
    • The carbon credit is half of a so-called cap-and-trade program. Companies that pollute are awarded credits that allow them to continue to pollute up to a certain limit, which is reduced periodically. Meanwhile, the company may sell any unneeded credits to another company that needs them. Private companies are thus doubly incentivized to reduce greenhouse emissions. First, they must spend money on extra credits if their emissions exceed the cap. Second, they can make money by reducing their emissions and selling their excess allowances.
  • CO2e:
    • CO2e means “carbon dioxide equivalent”. In layman’s terms, CO2e is a measurement of the total greenhouse gases emitted, expressed in terms of the equivalent measurement of carbon dioxide. On the other hand, CO2 only measures carbon emissions and does not account for any other greenhouse gases.
    • A carbon dioxide equivalent or CO2 equivalent, abbreviated as CO2-eq is a metric measure used to compare the emissions from various greenhouse gases on the basis of their global-warming potential (GWP), by converting amounts of other gases to the equivalent amount of carbon dioxide with the same global warming potential.
      • Carbon dioxide equivalents are commonly expressed as million metric tonnes of carbon dioxide equivalents, abbreviated as MMTCDE.
      • The carbon dioxide equivalent for a gas is derived by multiplying the tonnes of the gas by the associated GWP: MMTCDE = (million metric tonnes of a gas) * (GWP of the gas).
      • For example, the GWP for methane is 25 and for nitrous oxide 298. This means that emissions of 1 million metric tonnes of methane and nitrous oxide respectively is equivalent to emissions of 25 and 298 million metric tonnes of carbon dioxide.