Broadcast FULL HD IPTV content from 16 TV frequencies that can be ATSC / DVBS-S2 - or QAM(A&B) / DVBT / DVBT2 / ISDBT
EXAMPLE Model numbers can be ( H-16QAM-IP ---- H-16ATSC-IP ---- 16-8DVBS-IP )
The 16 Input Tuners choices are: All
The IP Output format is UDP multicast or multicast
FTA tuner inputs can be set to any non-adjacent carrier and converted to IP UDP unicast, multicast streams.
After setting the frequency the unit scans for Video/Audio programs and once discovered they can be converted individually to IP streams or re-modulated on different frequencies(channels) or a different modulation standard.
It supports up to 512 IP inputs and one IP (MPTS) output through GE1 and TS input for re-mux through 2 ASI ports. This is the next generation of Gateways of which will create a seamless conversion of RF programs to IP TS that are easily managed via a secure NMS system developed by Thor to help distribute all of your programs via IP and ASI. Convert 16 CATV in either DVBS2, QAM, or ATSC to IP or Transmodulate one format of RF to another form of RF. This family of products equipped with 16RF tuners is model dependent for QAM/ ATSC/ DVBS2 and works as RF to IP Gateway and can output Multicast or Unicast also can act as an RF Translator.
Because we use RF Tuners with specific modulation formats, these models are all independent of each other and must be ordered correctly because they are hardware based; we offer them in standards used across the globe so you can use your specific modulation standard for your country (please check model selection, reach out to your local dealer or call Thor directly). Essentially there are 3 hardware sets we manufacture, one specifically for ATSC, one for DVBS-S2, and the third is for QAM (the QAM model has built in modulation standards for QAM Annex A and Annex B, DVB-T, DVB-T2, and ISDB-T; this is selectable through the NMS GUI)
- ATSC to IP (SPTS Mode) Each ATSC frequency subchannel Transport strem can be cherry-picking and encapsulated to IP Multicast or unicast stream
- ATSC to IP (MPTS mode) all subchannels are being converted to one MPTS stream
- Auto PIS's detection on the tuner input and automated passes on the IP output
-It can be used as an ATSC3 Lighthouse Station Tuner, receive an IP gateway
Other models are available: H-16ATSC-IP-16ATSC 16 ATSC to 16 ATSC trans-modulator with VCT edit, H-16ATSC-IP-16QAM : 16 ATSC to 16 DVB-C QAM- trans modulator with VCT edit,
Input |
16 INPUT FTA Tuner selection:: DVB-S/S2 OT ATSC or DVB-C Annex A/B QAM (Model dependent) |
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512 IP (GE1only)input over UDP and RTP protocol |
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2 ASI input, BNC interface |
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Tuner Section |
DVB-S |
Input Frequency |
950-2150MHz |
Symbol rate |
2-45Msps |
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Signal Strength |
-65~-25dBm |
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FEC Demodulation |
1/2, 2/3, 3/4, 5/6, 7/8 QPSK |
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DVB-S2 |
Input Frequency |
950-2150MHz |
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Symbol rate |
QPSK 1~45Mbauds 8PSK 2~30Mbauds |
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Code rate |
1/2, 3/5, 2/3, 3/4, 4/5, 5/6, 8/9, 9/10 |
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Demodulation Mode |
QPSK, 8PSK |
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Multiplexing |
Maximum PID Remapping |
128per input channel |
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Function |
PID remapping (automatically or manually) |
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Accurate PCR adjusting |
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Generate PSI/SI table automatically |
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Modulation Output |
Modulation Output format |
ATSC or DVB-C Annex A / B QAM ( model dependendt, please chek model selection) |
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Standard |
EN300 429/ITU-T J.83A/B or 8VSB ( ATSC model ) |
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MER |
≥40db |
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RF frequency |
50~960MHz, 1KHz step |
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RF output level |
-20~+10dbm(87~107 dbµV),0.1db step |
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Symbol Rate |
5.0Msps~7.0Msps, 1ksps stepping |
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Constellation |
16/32/64/128/256QAM |
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J.83A |
J.83B |
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Constellation |
16/32/64/128/256QAM |
64/256 QAM |
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Bandwidth |
8M |
6M |
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System |
Remote management |
Web NMS (10M/100M) |
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RF Out |
16 DVB-C output or ATSC ( model dependendt, please chek model selection) |
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IP Out |
1 IP (MPTS) output over UDP and RTP/RTSP (GE1 only) Mirrors one carrier |
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Language |
English |
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Software Upgrading |
Web |
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General |
Dimension (W*D*H) |
482mm×300mm×44.5mm (1RU 19x8x3) |
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Weight |
3.7kg |
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Temperature |
0~45°C(Operation) ; -20~80°C(Storage) |
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Power |
AC 100V±1050/60Hz; AC 220V±10%, 50/60HZ |
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Consumption |
25W |
Yes, absolutely, the device can scan and discover all subchnnelTS insight the physical ATSC carrier, any subchannel transport strem can be encapsulated to its on IP strem of your choice. you can also re-map the PID's as well. This is the perfect solution for ATSC to ATSC3 transformation for lighthouse tv programming channel sharing receiver and IP gateway
How many of each signal are you trying to encode? Where is the Youtube source coming from?
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I would think 8 RF channels, 1 or 2 HDMI, and YouTube would be via web.
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and what protocol on multicast did you require?
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youtube is from the web, but in order to integrate, you need to receive it, then encode it again
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I watched YouTube video for the 16 rf tuner to IPTV to qam. Not to knowledgeable in this area, a network engineer by trade. Multicast would be UDP. Perhaps a Firestick or Roku device to get YouTube.
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Okay so this would be a multi device setup.
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We can use RF to IP Gateways' for your 8 ATSC channels
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Then an encoder for XX amount of HDMI inputs you need.
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Those IP outputs from those devices would all go to one switch and from there you'd have all your multicast streams.
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Which part numbers should I look at?
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H-8ATSC-IP
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this is the gateway for RF to IP
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2 HDMI input encoder for HDMI to IP
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Excellent thank you
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Do you want to use it on LAN or WAN?
I'm assuming WAN, in this case, UDP multicast would not work.
What you can do is stream your Video to Youtube using RTMP
protocol, and give all your friends and family, private links
You can use this encoder for this purpose :
https://thorbroadcast.com/product/4-channel-hdmi-cvbs-network-encoder-streamer-udp-rtp-unicast-multicast-8230.html
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We need between 6 and 12 TV channels (ATSC channels), we are using the camera below and we can enable multicast on these cameras, we are currently using H264 as these cameras are connected to a DVR for recording and we cannot change it, we may have to use the converters that you informed.Bosch | AUTODOME IP 5000i IR
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Question 2
If we use the device below, will we still need the converter?
https://thorbroadcast.com/product/iptv-to-16-32-clear-channel-rf-qam-atsc-modulator.html
Because these cameras are H264, we need to convert and encode those transport streams to Mpeg2 and then modulate onto ATSC for RF to your television.
1)
I understand your point. How many channels do you need to modulate?
We do have 8-channel HDMI modulators available which generate valid channels and static images even without an HDMI source connected.
Therefore, you could use simple 8 ATSC to HDMI decoders with an 8-channel modulator.
This way, even if you lose the signal for some reason, the TVs will retain the channel information.
For the 20 channels, you would need 20 ATSC STBs and 3 H-Thunder-8 modulators combined together. Each modulator would generate unique 8 channels, which you can then merge together.
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So, to make this clear, our ATSC to QAM gateway works exactly like BT. This is why I proposed a different solution.
If you use ATSC decoders combined with the 8ch HDMI modulator, you will not have this issue.
The 8ch HDMI modulator has a constant output whether HDMI is connected or not (the TS is constantly generated), so TVs will never lose channel information regardless of whether they receive HDMI video or not.
Please let me know if this is clear
1) Usually, satellite dishes don't send high-frequency C-Band signals over coaxial cable. Instead, installed LNBs downconvert C-band frequencies to a lower frequency band.
The satellite dish reflects the signal onto the LNB, which is mounted on the arm of the dish.
The LNB amplifies the signal received from the satellite and downconverts it to a lower frequency, enabling it to be transmitted through a coaxial cable to the receiver.
The satellite LNB works as a downconverter by converting the high-frequency satellite signal received by the dish into a lower frequency signal known as the L-band.
The L-band frequency range typically used for satellite communication is between 950 MHz and 2150 MHz.
The satellite LNB converts the received satellite signal, which may be in the Ku-band (10.7 GHz - 12.75 GHz) or C-band (3.7 GHz - 4.2 GHz), into a lower frequency signal in the L-band range.
Once converted to the L-band, the following devices can be used :
F-Lband-TxRx 1 L-band over fiber TX/RX Kit
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2) In this case, it is not so straightforward; it is impossible to
digitize the L-band spectrum and send it over IP.
However, in some cases, we can tune into specific DVBS/S2 channels and
convert TS (MPEG transport stream) videos to IP.
The video channels need to be free-to-air, clear, and not encrypted.
Please check this product, the 16ch DVBS/S2 to IP gateway.
The unit has 16 individual satellite tuners, and each tuner can be set
to a different satellite DVBS/S2 (frequency) channel.
Any videos from this channel can be output as UDP multicast streams.
These streams can be sent over the LAN Ethernet connection.
H-16DVBS2-IP
1) The highest density unit we make for QAM to IP is this model: H-16QAM-IP
2) Each of the 16 ATSC channels has an average of 3-4 subchannels, resulting in a total of 48-64 subchannels, other words, each TS (Transport Stream) has its own UDP SPTS multicast stream
3)
Thank you for your inquiry.
As you correctly pointed out, the H-8ATSC-IP or H-16ATSC-IP gateway will output all TS's UDP multicasts from the 8 ATSC carriers.
But the unit works as a gateway and is completely transparent; whatever encoded signal is carried on the RF will be outputted on the IP. We can change PIDs or other PSID information, the encoded video and audio original format remains the same. In other words, the video encoded format and resolution will be exactly the same as the original format of the ATSC channels.
The only way we could achieve a resolution change would be by decoding all your videos to HDMI format first and then re-encoding all of them using an HDMI encoder.
We can use a simple ATSC STB, such as the H-STB-QAM-ATSC, to decode it to HDMI.
We have many different encoders, but for your specific needs, you most likely require MPEG2 with AC3 Audio. In this case, the most suitable option would be our 4ch HDMI encoder H-4HD-EMH.
https://thorbroadcast.com/product/4-hdmi-broadcast-encoder-iptv-streamer-and-asi-out-mpeg2-8230.html
If H.264 encoding is sufficient, we also have 24ch encoders available -H-HDPerformux-24
https://thorbroadcast.com/product/4-8-16-24-hdmi-iptv-streaming-8230.html/216
Please don't hesitate to give me a call if you have any questions.
The Advanced Television Systems Committee (ATSC) standards dictate how TV signals are broadcast and received. Two of the most notable standards are ATSC 1.0 and ATSC 3.0, and they differ in various technical aspects, including their physical layer characteristics.
ATSC 1.0 (also just "ATSC"):
Modulation: ATSC 1.0 uses 8-VSB (8-level Vestigial Side Band) modulation. This is essentially a digital version of amplitude modulation and was chosen mainly for its compatibility with the existing NTSC system and its simplicity.
Transmission: It operates in the 6 MHz VHF and UHF TV channels.
Payload: The effective data rate for ATSC 1.0 is about 19.39 Mbps per 6 MHz channel.
Performance: In practice, 8-VSB is not very robust against multipath interference. This means that in certain areas (like urban canyons) or with particular types of interference (like moving vehicles), ATSC 1.0 can suffer from reception issues.
ATSC 3.0:
Modulation: ATSC 3.0 uses OFDM (Orthogonal Frequency Division Multiplexing), which is a type of multi-carrier modulation. This makes it much more robust against multipath interference than 8-VSB. It can also accommodate various modulation constellations including QPSK, 16QAM, 64QAM, and 256QAM, depending on the desired trade-off between data rate and signal robustness.
Transmission: Like ATSC 1.0, it operates in the 6 MHz VHF and UHF TV channels. But with its adaptive capabilities, it can adjust based on reception conditions.
Payload: Because of its adaptive nature, the effective data rate for ATSC 3.0 can vary. However, it can theoretically achieve higher data rates than ATSC 1.0 in optimal conditions.
Performance: Being based on OFDM and having adaptive capabilities, ATSC 3.0 is designed to be more robust against various interference sources, providing better indoor reception and mobile reception. It also supports MIMO (Multiple Input, Multiple Output) technology, further enhancing its reception capabilities.
Additional Features: ATSC 3.0 is not just an upgrade in terms of physical layer characteristics. It comes with other enhancements like support for 4K UHD, high dynamic range (HDR), better audio quality with Dolby AC-4, and even interactive features and hybrid content delivery in combination with broadband.
In summary, while ATSC 1.0 was a significant step forward from the analog NTSC system, ATSC 3.0 is a more advanced and flexible system designed to meet the needs of modern broadcasting, combining over-the-air transmission with broadband for a comprehensive and interactive viewer experience.
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OFDM (Orthogonal Frequency Division Multiplexing) is a modulation scheme that has found its way into various modern communication standards due to its robustness against multipath interference and its efficient use of the spectrum. Here are several notable standards and systems that utilize OFDM:
Wi-Fi Standards:
Digital Subscriber Lines:
Mobile Communication Standards:
Digital Terrestrial Television:
Digital Radio:
Power Line Communication:
High end state of the art decoder with RF tuner, advanced IP streaming, front LCD confidence monitor, and supports 608 and 708 closed captioning. RF tuners for DVB-S2, ATSC, and QAM are available. All settings and alarm information are available through web browser based network management console.
Four independent RF tuners demodulate the entire carrier band frequency to IPTV MPTS, ASI and CATV QAM. High density program stream IRD for satellite, terrestrial ATSC, DVB-T, ISDB-T and QAM cable TV applications. ASI input for multiplexing additional TS programs to output simultaneously. 5 different RF tuner options available: ATSC, DVB-S2, DVB-T, ISDB-T or QAM (model dependent)