Aggregator

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Denied both the Petition for Declaratory Ruling and the Demand for Carriage

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The authors are the founders, respectively, of StreamGuys and Barix AG.

Reliable urban performance is particularly important for competing with satellite, which often has dropouts even in cities with terrestrial repeaters.

As with most things in the broadcast universe, the transition from legacy to IP workflows has been gradual. In radio, this is perhaps best represented in the STL category.

For one thing, IP networks were uncharted, unproven territory for audio transport. The less reliable nature of IP as a transport medium versus tried-and-true T1/E1 lines was an immediate concern for broadcasters. From dropped packets to network outages, time spent off the air is money and listeners lost.

But there were other concerns as well. Working with IP meant learning an entirely new operation; configuration processes often required IT specialists to open firewalls and establish IP addresses on send (encode) and receive (decode) devices — a starting point that caused major frustration and confusion for many. This would grow even more complex for broadcasters seeking to adopt IP for point-to-multipoint architectures such as program syndication.

Once operational with live, local area connections, these send and receive devices, along with other boxes in the architecture that began to speak digital, required a great deal of local management and monitoring to ensure consistent reliability. That required being on-premise to manage all of these systems on the network.

Architecture of an uncompressed reflector and remote encoder system.

Security was also a concern — a concern that remains, but continues to grow stronger thanks to more secure solutions, and a better understanding of how broadcasters should protect their networks.

Early innovations like the Barix Reflector Service aimed to change these dynamics by providing a plug-and-play solution that simplified configuration, enhanced security and established a future foundation for cloud management. As these challenges have been addressed more strongly and broadcasters transition to IP more aggressively, the next logical question was how to optimize audio quality and support new media services over the network.

Radio has often been an industry of compromise; and with IP transport that compromise has been to the detriment of great-sounding audio. For radio studios and content owners in the adjacent audio production landscape, the focus is on creating high-quality, impactful audio. On the internet, the industry begrudgingly has accepted compressed formats — albeit for good reasons.

MP3 compression was widely accepted when the internet was slow; and in terms of compressed formats, it remains the most reliable when it comes to managing program-associated metadata. Nowadays, connections of 10 Mbps, 100 Mbps and even 5 Gbps are supporting 4K video to consumers, along with more efficient metadata management. It is now possible to send uncompressed streams over once-unthinkable 4G connections, for example, where T1 or better was traditionally necessary.

The question remains: With upload bandwidth no longer a concern, why compromise a radio station’s audio quality with compression?

Compressed formats still have a role in content networking and distribution, but when packaged for last-mile delivery to the consumer, the concept of “no compromise” in the signal chain is enormously important. This, along with a desire to support new media services and business models, makes an increasingly stronger case for broadcasters to move to an uncompressed IP transport service.

MOVING TOWARD GREATNESS

Similar to how broadcasters grew comfortable with IP, operating within the cloud is no longer a technical uncertainty. The transition has been similarly gradual, but the evidence exists that moving to the cloud is both operationally sound, while also simplifying systems management. This also reduces exposure to security risks, as the devices within the architecture are phoning home to the CDN or service providers, versus living inside the broadcaster’s network.

For example, there is no longer a need to run encoders on-premise for an uncompressed service. In most cases, the in-studio overhead is reduced to a stable desktop solution — typically well under $1,000.

Today’s premium encoders no longer need to sit inside the studio environment, and instead will reliably take in an input signal and its associated metadata in the cloud. In addition to reducing equipment costs and maintenance, operationally this cloud-based architecture unlocks the potential to mix-and-match digital signage processors, as well as codecs. The latter provides the flexibility to repackage program audio in HLS or segmented formats required for the radio affiliate, tower and or/consumer.

The metadata component unlocks a lot of this potential and flexibility at the final production stage. In addition to simplifying encoding into several formats, the presence of metadata provides more information to the listener to visualize and enhance the user experience. That same information also simplifies royalty reporting for the artists.

Enabling the service comes down to a stable, dedicated connection on the WAN interface — the same configuration that an ISP would embrace — that can support a bandwidth payload of 1.4 Mb per second. A 1.4 Mbps payload will support uncompressed PCM audio at 44.1 kHz, which delivers a human resolution up to 20 kHz — the standard for compact disc audio. This is representative of the Nyquist frequency, delivering a high-fidelity signal at approximately half of the sampling rate.

PCM audio, which represents the starting point of the uncompressed audio, remains a more reliable format for external IP distribution landscape. While AES67 inside the studio has come to fruition, PCM is still better equipped to tolerate the latencies and network condition variables of long-haul IP transport; our tests and real-world deployments prove latency at sub-1 second, with very minimal packet loss.

With more data moving across the network in an uncompressed format, packet loss or slight bandwidth interruptions will have minimal impact on the resulting audio quality.

There will come a time where 192 kHz resolution will be more reliable to manage over long distances, but PCM will provide the high fidelity of an uncompressed audio service with optimal reliability on today’s networks.

SOLVING PROBLEMS

While understanding the path to uncompressed transport is necessary, what matters most to broadcasters is solving problems and supporting new services. Let’s outline some of these scenarios, the value that an uncompressed transport platform delivers.

Quality Sourcing

Operating within a cloud workflow requires that the broadcaster send the program audio data into the cloud. While this can be achieved with a compressed stream, that signal will require further compression from downstream transcoding or transrating, among other processes. The more the audio is encoded and compressed, the greater likelihood of stream latency, undesirable audio artifacts and other issues with quality of experience.

With uncompressed source audio, a single encoding stage will support a varied bouquet of codecs and bitrates required for many consumer formats. And, with one device accommodating all encoding, the outputs are more tightly aligned from a latency perspective. This remains true when outputting different protocols, such as RTMP and HLS, at the encoding stage.

Therefore, working with uncompressed source audio — in addition to enhancing sound quality for audiences — will deliver a wide array of tightly aligned outputs encoded once from the master quality source.

Encoder Upgrades

As referenced earlier, moving encoders to the cloud introduces several new operational efficiencies, both in terms of upgrade and network growth.

On-premise encoders are offered in two flavors: a hardware device with fixed, limited CPU and RAM resources, and a software solution that typically runs on a PC or Mac. Both offer limitations that are amplified when working within an uncompressed environment.

The built-in capabilities of a hardware encoder are typically finite, and upgrades are often limited by what the vendor makes available. Any significant changes, such as adding a new codec or an increase in CPU processing, will likely require replacement of the encoder, with a potentially lengthy configuration process to bring the new system online.

While a software encoder is typically easier to replace, the supporting computer infrastructure hosting the software may require an upgrade. Over the long term, the management of that software, computer hardware and operating system will escalate costs and labor — and potentially put more stress on an already overburdened IT department.

Cloud encoders offer a simpler upgrade path. Most can be sized on the fly to amplify computing resources without wasting unnecessary resources and power, while also eliminating the need to replace the OS or software. An increase in available CPU, RAM and/or disk resources can be executed through a simple reboot process.

Scaling the infrastructure is also much easier in the cloud environment, with greater flexibility to increase the number of encoders efficiently without burdensome integration costs and labor.

Systems Management

The audio contribution and distribution pool continues to broaden, and broadcasters are finding themselves more limited by the locations of their on-premise encoders. For example, a remote contribution application may be limited by the resources and gear of the corresponding studio. Perhaps the content has been supplied to an affiliate that has no control of the master studio.

More specifically, an on-premises encoder increases the challenge of encoding at the right point in the signal chain. If the on-premise encoder is not at the precise location where the broadcaster desires, this means that encoding at the distribution point to the end user or desired application may not be possible — potentially introducing more than one encoding stage in the workflow.

Encoding in the cloud solves this problem by offering the option to insert the encoding output at any relevant place in the signal chain. If the broadcaster wants to condition and process a signal prior to sending to an affiliate, that affiliate could use an uncompressed master signal to feed their headend. From there, the uncompressed feed can be transported without any encoding required. Instead, a decoder can be supplied that can pass through the unmodified source at very low latency.

Using a cloud encoder also enables the broadcaster to send high- and low-bitrate signals in two formats, such as HE-AAC v2 and AAC-LC — and then output them as both RTMP, HLS and Icecast audio sources. A single uncompressed signal at the studio, with a fixed bandwidth rate of 1.4 Mbps, is all that is required, which equates to much less than the combined total of sending high and low bitrates for each protocol.

The overarching benefit here is that the management burden at the studio is reduced to one output to support a wide array of audio contribution and distribution requirements.

 

OUT IN THE REAL WORLD

Philadelphia-based WXPN, the public radio service of the University of Pennsylvania, is one example of a major broadcaster that has embraced the benefits of uncompressed audio over IP for program syndication. The broadcaster set out to develop a more sustainable distribution model for its XPoNential Radio channel, leveraging the Reflector Service from StreamGuys and Barix.

XPoNential Radio was originally distributed to affiliates via satellite and offered only for use on HD2 or HD3 channels. WXPN wanted to widen the usage of the channel to include primary broadcast, and while it continues to use satellite for national programming, the station sought an alternative, sustainable distribution model for the smaller-scale XPoNential Radio. Despite cost-effectiveness being one of the station’s motivations, quality and reliability were also key criteria.

The WXPN architecture leverages uncompressed PCM audio, which is transported between the encoding and decoding endpoints across the CDN infrastructure, while link management is simplified through a cloud-based portal. The station has achieved lossless, CD-quality audio enabled by uncompressed delivery to affiliates as far away as Alaska. New affiliates plug in Ethernet, power and audio cables to receive XPoNential Radio programming. Affiliates connect using 1.4 to 1.5 Mbps of bandwidth, which is plenty to receive the uncompressed signal and deliver it to consumers.

Moving the service to the cloud simplifies management, with station personnel able to access the portal to confirm that all clients are connected and streaming. The portal also allows operators to start, stop and configure delivery to each affiliate. Service can also be terminated for any client directly through the management portal.

Affiliates also don’t need any “special” internet connectivity to use the service. A very modest 1.5 Mbps of bandwidth is enough to receive the uncompressed signal, and most consumer-level internet connections are sufficiently reliable and stable. Even WXPN does not require hefty bandwidth regardless of how many affiliates they serve, as the Barix Reflector service takes a single feed from the origin (a Barix codec), with StreamGuys’ delivery network scaling out the bandwidth for reaching recipients.

 

BRINGING IT TOGETHER

As we look deeper into the future, the enhanced reliability and flexibility of an uncompressed IP service will provide a strong value proposition that will be hard to deny. Uncompressed STL will simply deliver T1-like audio quality over IP unhindered by downstream processes like transcoding, while syndicators will save a great deal of money and labor in the transition from satellite to IP for contribution and distribution.

Moving encoders into the cloud will support more formats and services while reducing the systems management burden, both at the studio and elsewhere in the audio contribution and distribution chain. The opportunity to better manage metadata alongside the uncompressed program audio stream will strengthen business opportunities and the consumer experience. And, the adaptability to accommodate even high-resolution formats as network conditions evolve will surely open new doors from both a service provision and listener experience perspective.

Kiriki Delany, a musician, computer geek and multimedia specialist, founded StreamGuys in 2000. Johannes Rietschel, a communications engineer by heart, founded Barix AG in 2000 and serves as CTO.

The post Make the Most of Your Uncompressed Opportunities appeared first on Radio World.

The author is president of WorldDAB.

LONDON — The last 12 months have been an exciting period for DAB digital radio. At the end of last year, the European Union adopted the European Electronic Communications Code (EECC), which will require all new car radios in the EU to be capable of receiving digital terrestrial radio. Shortly afterwards France confirmed the launch of national DAB+ with the support of all their major broadcasters.

Patrick Hannon

DEVELOPMENTS

Progress has continued throughout 2019 — in May, Austria launched national DAB+ services and in the summer, Sweden saw the launch of national commercial DAB+.

More established markets have maintained their momentum in driving DAB+ digital radio forward. Following Norway’s switch-off in 2017, Switzerland has confirmed the switch-off of national FM services by the end of 2024; Germany and the Netherlands continue to make strong and steady progress, and the United Kingdom is seeing record levels of digital listening.

Belgium, the country hosting this year’s General Assembly, is also seeing high levels of activity, with both the Flemish (Dutch Speaking) and Wallonia (French speaking) regions demonstrating their commitment to the growth of DAB+.

[Read: EuroDAB Italia Begins Airing BBC World Service]

A further important development in Europe is the introduction of regulation requiring consumer receivers to include DAB+. Such laws will come into force in Italy and France in 2020, while a similar law — coming into effect in December 2020 — has just been passed in Germany. For WorldDAB, encouraging the adoption of such rules in other markets will be a priority in 2020 and beyond.

Joan Warner, CEO Commercial Radio Australia, addresses the audience at the 2018 WorldDAB general assembly.

We are also seeing interesting developments outside of Europe, with numerous markets pursuing trials in the Middle East, North and South Africa as well as Southeast Asia, and more significant developments in Australia and Tunisia. The former is now seeing its highest ever levels of DAB+ radio being fitted in new cars, while the latter — which is a potential gateway to the wider Arabic speaking region — has recently launched the first regular services in North Africa.

PROTECTING RADIO BROADCASTERS

Against this positive background, it’s increasingly clear that broadcasters and policy makers are concerned about the growing power of the tech giants in relation to national, regional and local content providers. This is likely to be a key topic of discussion at this year’s General Assembly. As WorldDAB, our focus will be on highlighting the contribution which DAB+ radio makes toward promoting and protecting the interests of national and local radio broadcasters.

Of course, the digital radio listening experience is evolving, and DAB+ is not the only digital platform. The key to long-term success is to position DAB+ at the heart of broadcasters’ digital strategies, and ensure its unique characteristics are preserved as the radio industry moves forward.

All of the above topics will be covered over the two days of the event held in Brussels, Belgium, and we look forward to seeing as many of you as possible there.

 

 

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Dave Kolesar is senior broadcast engineer for Hubbard Radio. Mike Raide is manager of broadcast engineering at Xperi Corp. WWFD is serving as a real-world testbed for MA3, which the authors say provides more coverage and less adjacent-channel interference than hybrid MA1.

For AM stations, today’s HD Radio technology hasn’t done much to level the playing field with FM, satellite and streaming services such as Spotify. One major reason is that the current system uses the MA1 waveform, which, although it provides HD Radio capabilities such as high-fidelity audio, artist information and album artwork, may do so in only part of a station’s coverage area.

Fig. 1: The MA1 (hybrid) waveform.

MA1’s digital carriers also require three times more bandwidth than the analog signal, so they create more adjacent channel interference — an annoyance that’s among the reasons why people choose alternatives such as FM, SiriusXM or Pandora. So by providing a better listening experience for some stations, MA1 actually undermines others.

But HD Radio has another, far superior waveform that AM stations could use: MA3, which minimizes the interference problem and extends HD Radio’s capabilities to the vast majority of a station’s coverage area. The difference is MA3 is an all-digital signal, whereas MA1 is a hybrid of analog and digital.

In the MA1 mode, the analog carrier is flanked by primary, secondary and tertiary OFDM carriers, each with its own power level. In MA3, the primary carriers replace the analog carrier, and their power increases by 15 dB. MA3 also relocates the secondary carriers to the upper sideband and the tertiary carriers to the lower sideband, and both have their power increased to –30 dBc.

Thus the MA3 mode requires 20 kHz of bandwidth, while MA1 needs 30 kHz.

Fig. 2: The MA3 (all-digital) waveform.

MA3’s spectral efficiency provides two major benefits. First, MA3 protects the listening experience for first and second adjacent stations because the narrower bandwidth means less “slop” onto their signals, which is a longstanding problem with MA1, particularly after sunset. Second, MA3’s lower bandwidth requirement means it’s more likely to be capable of using antenna systems that were inadequate for MA1. As a result, more stations potentially can upgrade to digital because MA3 enables them to avoid the expense of replacing their antenna system.

Over the past year, WWFD in Frederick, Md., has served as a testbed that vendors, broadcasters and the FCC can use to understand how upgrading a station to MA3 affects antenna systems, transmitters and engineering practices. Here are the lessons learned so far, and a preview of the drive-test results that will be covered in a follow-up article.

THE STRATEGY AND BUSINESS CASE FOR GOING ALL-DIGITAL

Fig. 3: WWFD retuned daytime antenna Smith chart.

Owned by Hubbard Radio, WWFD runs an adult album alternative format on 820 kHz. It operates 4.3 kW non-directional during the day and switches to a 430 W two-tower array at night.

WWFD also has a 160 W translator, W232DG, on 94.3 MHz. Most WWFD listeners migrated to the translator after it signed on in July 2017, which made it feasible from a business perspective to replace the analog carrier with MA3 on an experimental basis.

If those tests were successful enough to continue using MA3, the translator could be used to educate listeners about the availability and benefits of the all-digital AM outlet. One example is explaining that when the translator’s signal starts to fade, they can switch their vehicle’s HD Radio to 820 and keep enjoying crystal-clear music for another 30–50 miles.

Fig. 4: WWFD retuned daytime antenna Smith chart marker data.

The FCC granted Hubbard a one-year STA to operate WWFD in MA3 mode, a switch that took place on July 16, 2018. Getting to that point took a lot of time, effort and collaboration with Kintronic Laboratories and Cavell, Mertz and Associates for the antenna system, and Broadcast Electronics, Nautel and GatesAir for the transmitters. Xperi Corp. lent its expertise to set up the digital transmitters, and to verify the operation of the antenna system.

GETTING A 58-YEAR-OLD ANTENNA SYSTEM DIGITAL READY

Fig. 5: WWFD retuned nighttime antenna Smith chart.

Early on, the MA3 mode would be used on 1670 kHz via a diplex into the existing 820 kHz antenna system. The 820 antenna system had undergone several modifications over the decades, including tower changes as part of a frequency change in 1987, and had not been characterized since it was last modified in 1991.

The first step was to measure every coil and capacitor, verify schematics and correct mistakes. Kintronic Labs helped with this process by analyzing the results and recommending changes. For example, they determined that the antenna system’s day and night performance was inadequate for all-digital transmission — no surprise, considering that WWFD has always been entirely analog and never used the MA1 mode. To support digital operations, a rule of thumb says that the SWR should be 1.4:1 ±15 kHz from the center frequency. WWFD’s was 1.8:1 at 10 kHz for the day mode, and 2.1:1 at 10 kHz for the night mode.

To bring things to the desired levels, Kintronic Labs redesigned the phasor and ATU networks. The goal was to enable optimal phase shifts to provide enough bandwidth to support all-digital transmission, while also keeping the number of new components to a minimum.

Several challenges stood in the way. For example, WWFD’s two towers are less than 90 degrees high, which restricts the bandwidth of the tuning units. The system also has filter and detuning networks both for the 1670 kHz operation and to protect another station whose 930 kHz facility is less than a mile away.

Fig. 6: WWFD retuned nighttime antenna Smith chart marker data.

One set of changes involved the ATUs, where the L networks were converted into T networks so the phase shifts could be adjusted to optimize bandwidth. Inside the phasor, the T networks that adjust each tower’s phase shift were converted to series LC networks. This enabled fine-tuning controls for the larger shifts at the ATUs. Longstanding issues needed to be addressed as well. One example is the discovery of an unbonded, abandoned RPU line, which had created extra capacitance across one tower’s base insulator, adversely affecting the tower’s self-impedance.

The daytime network uses only the T network in tower 2, where the tuning process simply required adjusting for an impedance of 50 + j0 at the transmitter. With all of the modifications and repairs, the bandwidth turned out to be more than adequate, with a measured SWR of less than 1.35:1 at ±10 kHz.

The two-tower directional nighttime array was more complicated. Dummy loads were inserted at each ATU’s input, with an Array Solutions Power AIM 120 looking backward into each network from the antenna side. The matching networks were then set for the complex conjugate of the drive point impedance measured when the array had been in substantial adjustment.

With the networks reconnected, the phasor controls were used to put the array back into substantial adjustment. A bridge was inserted at the output of each phasor port, and the transmission lines were matched to 50 + j0 using the “cut and try” method.

Finally, the input network to the phasor (i.e., the “common point”) was adjusted to provide the transmitter with an impedance of 50 + j0. Now in tune, the night network was swept for bandwidth, and had an SWR of not more than 1.37:1 at ±10 kHz. The entire antenna system was now capable of passing the MA3 waveform.

FINDING THE RIGHT TRANSMITTER

For analog, WWFD uses a Harris Gates Five as the main transmitter, with a Nautel AMPFET Five for auxiliary service. Re-using the AMPFET Five for MA3 wasn’t an option because it can’t support digital, so a BE AM-6A was brought in as the new main transmitter. A Nautel AM IBOC exciter and BE ASi-10 were added to generate MA3 waveforms, and for testing and demonstrating interoperability between different manufacturers’ equipment.

Next, each transmitter’s audio input was connected to its exciter’s magnitude output, while each transmitter’s external oscillator input was connected to the phase output. The first round of tests used the Nautel exciter and AM-6A transmitter, with the balanced magnitude exciter output interfaced to the balanced (left) audio input of the transmitter through an H-Pad variable attenuator.

The tests followed the manufacturer’s instructions for implementing the MA1 mode. Once the transmitter was tuned properly for MA1 operation, the exciter was flipped to MA3 mode. The transmitter’s audio input was set to not exceed 95 percent negative modulation, while positive peaks were typically above 150 percent.

With a spectrum analyzer monitoring the transmitter’s RF output, the phase delay was adjusted for minimum spectral regrowth. Ideally this adjustment should be done with the secondary and tertiary carriers turned off (i.e., in MA3 core mode, with just the primary carriers being transmitted). That’s because some regrowth may be hidden underneath the secondary and tertiary carriers in the full MA3 mode.

Now optimized, the MA3 secondary carriers were turned back on. At ±25 kHz from the channel center, the regrowth was limited to –65 dBc with reference to the pilot channel. These results ensure compliance with the NRSC-2 spectral emissions mask.

DEVELOPING A NEW POWER MEASUREMENT PROCEDURE

Fig. 7: WWFD transmitter configuration.

The STA didn’t change WWFD’s licensed operating parameters for power output and directionality. But because the MA3 mode is an OFDM method of transmission, all-digital power can’t be measured using the traditional analog AM practices.

For example, MA3’s peak-to-average ratio is significantly higher than that of analog AM, so the transmitter’s power level meter may read inaccurately. Also, if the transmitter isn’t optimized for MA3 mode, the peak-to-average ratio may be reduced, and a different power level reading may result than if the transmitter been optimally adjusted.

Thus, a new procedure is necessary to verify that transmitters are operating at licensed power when in MA3 mode.

INITIAL DRIVE RESULTS DEMONSTRATE REAL-WORLD BENEFITS

Qualitative field strength measurements used the station’s existing Potomac Instruments FIM-21 meter, which was checked against an FIM-4100, which is specifically designed to handle the MA3 mode. The FIM-21 and FIM-41 meters indicate lower field strengths in MA3 than what a FIM-4100 reads because the latter has passband filters that encompass the entire waveform. As a result, measurements must be compared side-by-side, and a multiplication factor for each individual meter (due to variances in the IF filter sections for the FIM-21 and FIM-41 meters, or any superheterodyne meter) should be used when a qualitative check is desired, and a newer meter is unavailable.

Daytime drive tests used multiple vehicles’ factory OEM radios. Under ideal daytime conditions, the MA3 primary carriers can be decoded down to the 0.1 mV contour, as confirmed via reception reports and drive testing at or near Harrisburg, Pa., Breezewood, Pa. and Cambridge, Md. Critical hours propagation phenomena typically reduce reliable coverage to the 0.5 mV contour.

Nighttime MA3 reception generally follows the station’s nighttime interference free (NIF) contour: Wherever an analog carrier-to-noise ratio of 20 dB is achieved, the MA3 carrier will generally be received. Early evening reception goes well beyond the NIF. As co-channel skywave interference increases during the evening, coverage is reduced to the NIF. In the station’s 2.0 mV contour, in-vehicle reception was reliable, without zero dropouts in either the Frederick urban core or underneath bridges. Reliable urban performance is particularly important for competing with satellite, which often has dropouts even in cities with terrestrial repeaters.

The MA3 waveform is adversely affected by the deep nighttime null that WWFD uses to protect WBAP in Dallas. Drive testing shows that reception is lost on this axis before the predicted contour, due to the directional antenna system suppressing the center of the channel more than the sidebands. This is likely to be a common condition in arrays with high degrees of carrier suppression and disappears once off the null axis.

TO REVITALIZE, DON’T COMPROMISE

The work thus far by WWFD, Xperi and its other collaborators shows that MA3 has a viable, highly promising role in enabling the AM revitalization sought by both the industry and the FCC. This promise is reflected in NPRM petitions to allow MA3. One example is Bryan Broadcasting’s March 2019 petition, which subsequently received numerous positive comments in support. This growing interest and support among station owners, equipment vendors and the rest of the industry highlights why WWFD’s testbed is so important.

In particular, the drive tests demonstrate that MA3 can provide not only high-fidelity audio, but also album artwork, artist information and other data, throughout a station’s coverage area. All of these features will help AM stations compete with FM, satellite and streaming in both vehicles and homes.

Just as important, the drive tests show that MA3 avoids all of MA1’s biggest drawbacks, starting with excessive bandwidth requirements that result in adjacent-channel interference. Another is MA1’s annoying hiss due to how its digital carriers often bleed into the analog signal in receivers with wide IF bandwidth. Finally, unlike MA3, MA1’s digital carriers are 30 dB lower in amplitude than the analog carrier, which limits digital signal robustness and reception range.

Day and night drive testing currently is underway. Next time we will explore the lessons learned from those drive tests, and discuss further optimization of the antenna system as well as power measurement options.

Comment on this or any story. Email rweetech@gmail.com.

The post Upgrading an AM to All-Digital: Why, How and Lessons Learned appeared first on Radio World.

A hearing on C-Band spectrum, titled “Repurposing the C-Band to Benefit All Americans,” has been scheduled by the House’s Energy & Committee and its Communications & Technology Subcommittee for Tuesday, Oct. 29, at 10 a.m.

The use of the C-Band spectrum in the 3.7–4.2 GHz band is currently used by broadcasters and satellite operators, but is being considered for possible use by 5G.

[Read: FCC Wants Additional Comments on C Band Issue]

“The FCC must repurpose the C-Band in a manner that promotes competition, spurs the 5G revolution and yields revenue for important priorities here at home,” said Rep. Frank Pallone Jr. (D-N.J), Energy & Commerce Committee chairman, and Rep. Mike Doyle (D-Pa.), chairman of the Communications & Technology Subcommittee, in a joint statement. “There may be a need for legislation to reduce uncertainty and benefit Americans.”

They added, “What we don’t want is the Federal Communications Commission to become mired in litigation that slows 5G deployment. We must ensure the American people benefit from this process, and we look forward to discussing these important issues at the hearing next week.”

Information regarding the hearing, including a livestream, will be available on the Energy & Commerce Committee website.

 

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Those tornados Sunday night in Dallas sent KNON(FM) dark after a direct hit on the building housing the radio station’s studios.

Dave Chaos, station manager for KNON, was at home enjoying the Dallas Cowboys football game on TV when his radio station was literally blown away by the tornado.

“Great game but it was a horrible storm. I had a call at home that we had lost power at the radio station about an hour prior. Then the tornado hit the building and about all was lost,” Chaos says.

[Read: Months After Hurricane, WTJX Fights On]

The office building housing the radio station in North Dallas suffered major damage, including blown out windows. In addition, part of the building’s roof was blown off. Serious damage was done to the station’s main studio and offices, Chaos said. Some of the station’s broadcast equipment was damaged by the estimated 140 mph winds and broken glass and likely won’t be salvageable.

“We had several employees at the radio station when the tornado hit. They hid in the bathroom as the tornado roared past and shook the building. It scared them but they were uninjured,” he said.

KNON returned to the air less than 36 hours after the tornado, Chaos said, and continues to broadcast from a small brick building located at its transmitter site, which is located in Cedar Hill, approximately 20 miles southwest of its former studios. The transmission site remained intact following the storm.

“We are broadcasting at full power from an empty transmitter room and plugged straight to the transmitter. It’s about a 10 x 10 room. We have a few tables with a 16-channel Behringer mixer board, two CD players and two mics,” Chaos said. “We also have a USB connection into the board so we can plug laptops in with music to play.”

Chaos says the station will have to find a new permanent home since the damage to the station’s building is so severe. “We’ve already been told by the owners of the building we will not be able to rebuild there.”

KNON, which is owned by Agape Broadcasting Foundation, broadcasts at 89.3 MHz and also streams online. It plays jazz, punk, metal, gospel, R&B, Latin, blues, country, Cajun, reggae and Native American music, according to its website.

The radio station is a “nonprofit, listener-supported community radio station, which derives its main source of income from on-air pledge drives and from underwriting or sponsorships by local small businesses.”

The National Weather Service confirmed this week that a total of nine tornados hit the Dallas-Fort Worth area last Sunday night. The strongest twister, rated as an EF-3 by the weather service, packed 140-mph winds. No one was killed by the tornados and no major injuries were reported.

 

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The radio industry is mourning the death of long-time engineer Gary Lee Ellingson of Moorhead, Minn., who passed away on Oct. 11. He was 67.

According to an obituary on Inforum and the West Funeral Home in West Fargo, N.D., Ellingson was born to Oscar and Olga Ellingson of Thief River Falls, Minn., 24 years after the birth of his sister Helen. He was the youngest of four siblings, including Helen, Harry and Orville.

His father passed away after Ellingson turned two years old, and he and his mother regularly attended the Evangelical Free Church in Thief River Falls.

While working at a local radio station in the 1960s, Ellingson made a life-long commitment to religion and long talked about the correlation between current events and scripture. He pursued a career in missionary radio after attending Moody Bible Institute in Chicago in the fall of 1972. It was there that he met his wife, Billie Sue Shreve, and the two were married June 4, 1976, in Circleville, Ohio.

Ellingson went on to finish his college education at Northland Community College in Thief River Falls, including two years of electronics study at the Area Vocational Technical Institute, followed by Grace College of the Bible in Omaha, Neb.

While attending Grace, Ellingson worked full time as chief engineer for KGBI and KROA, two Grace radio ministries in Omaha and Grand Island, Neb. It was during that time that Ellingson developed a method of correcting interference between an antenna and the tower upon which it is mounted and distributing the mechanical load on the tower while allowing the antenna to be rotated around the tower. Through a friend in his Greek class at Grace, Ellingson was introduced to Wendell Miller, a registered professional mechanical engineer and patent agent in Goshen, Ind. Gary’s invention resulted in four United States Patents with the systems still being manufactured today.

Ellingson also worked for Motorola as a field service technician and then took a job as dispatcher-jailer at the newly constructed Law Enforcement Center in Thief River Falls where he installed all of the radio equipment.

Ellingson and Billie Sue moved back to Thief River Falls with their first two children, Daniel and Andrew, and he continued working in broadcast engineering as a field service engineer, and eventually went full time in manufacturing the antenna positioning system. He and a number of friends and relatives pooled resources to complete the patent process and went on to form Polar Research Inc.

The couple, with arrival of a third child, Mathew, moved to Moorhead, Minn., where Ellingson took a job teaching electronics at Moorhead Area Vocational-Technical School and he added a part-time announcer job at KFNW radio in Fargo. Their daughter, Kristin, was born shortly after moving to Moorhead.

In addition, he served as a pastor at New Hope Evangelical Free Church in Moorhead and went on to become director of engineering for the University of Northwestern in St. Paul, Minn., a missionary and liberal arts university.

Ellingson is survived by his children Daniel (Alissa) from Woodbury, Minn; Andrew (Krystyna) from Thief River Falls, Minn.; Matthew (Maria) from Minnetonka, Minn.; and Kristin from North Dakota. He is also survived by nine grandchildren: Samuel and Abigail from Woodbury; Gweneth, Logan, Farrah and Natalie from Thief River Falls; and Layla, Penny and Gloria from Minnetonka. He was preceded in death by his parents Oscar and Olga; his siblings Harry, Orville, and Helen (Adamson); and his wife Billie Sue, who passed away Dec. 1, 2018.

At Ellingson’s request, in lieu of gifts or flowers, please consider giving the equivalent amount to Ravi Zacharias International Ministries, 3755 Mansell Road, Alpharetta, Ga., 30022 or Bethel Church, 2702 30th Avenue South, Fargo, N.D., 58103.

Visitation will be held at West Funeral Home, West Fargo, N.D., on Oct. 23, with the funeral held at 11 a.m. on Thursday, Oct. 24, at Bethel Church in Fargo, N.D. Burial will be at Sunset Memorial Gardens in Fargo.

 

The post Radio Industry Remembers Engineer Gary Lee Ellingson appeared first on Radio World.

In this document, the Commission announces auctions of Priority Access Licenses for the 3550-3650 MHz Band, designated as Auction 105. This document proposes and seeks comment on competitive bidding procedures to be used for Auction 105.

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