Video: CPAC Case Study – Replacement of a CWDM System with an IP System

For a long time now, broadcasters have been using dark fibre and CWDM (Coarse Wavelength Division Multiplexing) for transmission of multiple SDI feeds to and from remote sites. As an analogue process, WDM is based on a concept called Frequency Division Multiplexing (FDM). The bandwidth of a fibre is divided into multiple channels and each channel occupies a part of the large frequency spectrum. Each channel operates at a different frequency and at a different optical wavelength. All these wavelengths (i.e., colours) of laser light are combined and de-combined using a passive prism and optical filters.

In this presentation Roy Folkman from Embrionix shows what advantages can be achieved by moving from CWDM technology to real-time media-over-IP system. The recent project for CPAC (Cable Public Affairs Channel) in Canada has been used as an example. The scope of this project was to replace an aging CWDM system connecting government buildings and CPAC Studios which could carry 8 SDI signals in each direction with a single dark fibre pair. The first idea was to use a newer CWDM system which would allow up to 18 SDI signals, but quite quickly it became apparent that an IP system could be implemented at similar cost.

As this was an SDI replacement, SMPTE ST 2022-6 was used in this project with a upgrade path to ST 2110 possible. Roy explains that, from CPAC point of view, using ST 2022-6 was a comfortable first step into real-time media-over-IP which allowed for cost reduction and simplification (no PTP generation and distribution required, re-use of existing SDI frame syncs and routing with audio breakaway capability). The benefits of using IP were: increased capacity, integrated routing (in-band control) and ease of future expansion.

A single 1RU 48-port switch on each side and a single dark fibre pair gave the system a capacity of 48 HD SDI signals in each direction. SFP gateways with small Embronix enclosures have been used to convert SDI outs of cameras to IP fibre – that also allowed to extend the distance between the cameras and the switch above SDI cabling limit of 100 meters. SFP gateway modules converting IP to SDI have been installed directly in the switches in both sites.

Roy finishes his presentation with possible future expansion of the system, such as migration to ST 2110 (firmware upgrade for SFP modules), increased capacity (by adding additional dark fibres ands switches), SDI and IP routing integration with unified control system (NMOS), remote camera control and addition of processing functions to SFP modules (Multiviewers, Up/Down/CrossConversion, Compression).

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Speaker

Roy Folkman 
VP of Sales
Embrionix

Video: Live Closed Captioning and Subtitling in SMPTE 2110 (update)

The SMPTE ST 2110-40 standard specifies the real-time, RTP transport of SMPTE ST 291-1 Ancillary Data packets. It allows creation of IP essence flows carrying the VANC data familiar to us from SDI (like AFD, closed captions or ad triggering), complementing the existing video and audio portions of the SMPTE ST 2110 suite.

This presentation, by Bill McLaughlin from EEG, is an updated tutorial on subtitling, closed captioning, and other ancillary data workflows using the ST 2110-40 standard. Topics include synchronization, merging of data from different sources and standards conversion.

Building on Bill’s previous presentation at the IP Showcase), this talk at NAB 2019 demonstrates a big increase in the number of vendors supporting ST 2110-40 standard. Previously a generic packet analyser like Wireshark with dissector was recommended for troubleshooting IP ancillary data. But now most leading multiviewer / analyser products can display captioning, subtitling and timecode from 2110-40 streams. At the recent “JT-NM Tested Program” event 29 products passed 2110-40 Reception Validation. Moreover, 27 products passed 2110-40 Transmitter Validation which mean that their output can be reconstructed into SDI video signals with appropriate timing and then decoded correctly.

Bill points out that ST 2110-40 is not really a new standard at this point, it only defines how to carry ancillary data from the traditional payloads over IP. Special care needs to be taken when different VANC data packets are concatenated in the IP domain. A lot of existing devices are simple ST 2110-40 receivers which would require a kind of VANC funnel to create a combined stream of all the relevant ancillary data, making sure that line numbers and packet types don’t conflict, especially when signals need to be converted back to SDI.

There is a new ST 2110-41 standard being developed for additional ancilary data which do not match up with ancillary data standardised in ST 291-1. Another idea discussed is to move away from SDI VANC data format and use a TTML track (Timed Text Markup Language – textual information associated with timing information) to carry ancillary information.

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Download the slides.

Speakers

 

Bill McLaughlin Bill McLaughlin
VP of Product Development
EEG

Video: Using AMWA IS-06 for Flow Control on Professional Media Networks

In IP networks multicast flow subscription is usually based on a combination of IGMP (Internet Group Management Protocol) and PIM (Protocol Independent Multicast) protocols. While PIM allows for very efficient delivery of IP multicast data, it doesn’t provide bandwidth control or device authorisation.

To solve these issues on SMPTE ST 2110 professional media networks the NMOS IS-06 specification has been developed. It relies on a Software-Defined Networking, where traffic management application embedded in each single switch or router is replaced by a centralised Network Controller. This controller manages and monitors the whole network environment, making it bandwidth aware.

NMOS IS-06 specification provides a vendor agnostic Northbound interface from Network Controller to Broadcast Controller. IS-06 in conjunction with IS-04 (Discovery and Registration) and IS-05 (NMOS Device Connection Management) allows Broadcast Controller to automatically set up media flows between endpoints on the network, reserve bandwidth for flows and enforce network security. Broadcast Controller is also able to request network topology information from Network Controller, which can be used to create a user friendly graphic representation of the flows in the network.

In this presentation Rob Porter from Sony Europe explains the basics of NMOS IS-06, showing in details how setting up media flows with this specification fits into the IS-04 / IS-05 workflow. Rob emphasise that all AMWA NMOS specifications are completely open and available to anyone, allowing for interoperability between broadcast and network devices from different manufacturers.

The next speaker, Sachin Vishwarupe from Cisco Systems, focuses on the future works on IS-06, including provisioning feedback (such as insufficient bandwidth, no route available from sender to receiver or no management connectivity), flow statistics, security and grouping (similar to ”salvo” in SDI world).

There is also a discussion on extension of IS-06 specification for Network Address Translation (NAT), which would help to resolve problems caused by address conflicts e.g. when sharing resources between facilities.

You can find the slides here.

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Speakers

Rob Porter Rob Porter
Project Manager – Advanced Technology Team
Sony Europe
Sachin Vishwarupe
Principal Engineer
Cisco Systems

Video: The Good and the Ugly – IP Studio Production Case Study

What’s implementing SMPTE ST-2110 like in real life? How would you design your network and what were the problems? In this case study Ammar Latif from Cisco Systems presents the architecture, best practices and lessons learned they gleaned in this live IP broadcast production facility project designed for a major US broadcaster. Based on SMPTE ST-2110 standard, it spanned five studios and two control rooms. The central part of this project was a dual Spine-Leaf IP fabric with bandwidth equivalent of a 10,000 x 10,000 HD SDI router with a fully non-blocking multicast architecture. The routing system was based on Grass Valley Convergent broadcast controller and a Cisco DCNM media controller.

As the project was commissioned in 2018, the AMWA IS-04 and IS-05 specifications providing an inter-operable mechanism for routing media around SMPTE 2110 network were not yet available. Multicast flow subscription was based on a combination of IGMP (Internet Group Management Protocol) and PIM (Protocol Independent Multicast) protocols. While PIM is very efficient and mature, it lacks the ability to use bandwidth as a parameter when setting up a flow path. Ammar explains how Non-Blocking Multicast (NBM) developed by Cisco brings bandwidth awareness to PIM by signalling a type of data (video, audio or metadata).

The talk continues by discussing PTP distribution & monitoring, SMPTE 2022-7 seamless protection switching and remote site production. Ammar also lets us see how the user interfaces on the Cisco DCNM media controller were designed which include a visualisation of multicast flow, network topology and link saturation of ports.

You can find the slides here.

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Speaker

Ammar Latif
Principal Architect,
Cisco Systems