JP2024043926A - Transmission system and transmission method, and IP gateway and effect device applied to the transmission system - Google Patents

Abstract

[Problem] To provide an IP gateway and an effect device that automatically find optimal phase setting parameters when constructing a system, suppresses increases in system design costs, and alleviates adverse effects on broadcasting when PTP (Precision Time Protocol) synchronization failure occurs. [Solution] An IP gateway applied to a master transmission system includes an RTP receiving unit that receives RTP packets transmitted via IP from an RTP transmitter and acquires header information from the RTP header of the RTP packet, a time synchronization unit that performs time synchronization based on PTP by transmitting and receiving PTP messages, a device setting unit that receives target phase information, a timing derivation unit that acquires timing information from the header information and derives the start timing of a process to convert RTP packets to SDI based on the timing information, device time information, and target phase information, and an IP/SDI conversion unit that starts processing according to the start timing. [Selected Figure] Figure 2

Description

Embodiments of the present invention relate to a transmission system and a transmission method applied to IP transmission, and an IP gateway and effect device applied to the transmission system.

Conventionally, in master transmission systems used in broadcasting technology, materials input from studios, line centers, server systems, etc. are automatically switched by a switcher according to a transmission schedule, effects are applied, and the materials are then encoded, multiplexed, and sent to a transmission system. Here, if the input materials are frequency asynchronous, a frame synchronization unit synchronizes them to the system.

The effect device that performs effect processing is composed of multiple stages, and includes superimposition that superimposes emergency information such as program providers, breaking news, earthquakes, and tsunamis on video, superimposition of chime sounds, and video and audio signals that are performed when switching programs. When there is heavy snow or typhoon, the main video signal is reduced to a corner, and weather information about heavy snow or typhoon is shown in the empty part like an L shape. .

Generally, effects devices that perform this type of effect processing start processing at a fixed phase relative to system synchronization, but in reality, there are transmission delays in the signal and processing delays in the preceding device, so the signal does not necessarily arrive at the desired timing. For this reason, effects devices have a line memory called an AVDL (Automatic Video Delay Line), which absorbs phase shifts of about one line. However, if the input phase shift relative to the system phase exceeds the range that the AVDL can absorb, the effects device will no longer be able to process the signal, resulting in an unnatural image. For this reason, it is necessary to properly manage the phase of the signal input to the effects device.

If each effect device has a frame memory, it is possible to process input signals of any phase, but frame memories require a large amount of memory resources and have very high input/output latency. In particular, input/output latency impairs the real-time nature of broadcasting.

In recent years, a transmission method has been developed in which SDI (Serial Digital Interface) is packetized as RTP (Real-time Transport Protocol) packets and transmitted over an IP (Internet Protocol) network (see Non-Patent Documents 1, 2, and 3).

SMPTE ST2110-20 SMPTE ST2110-30 SMPTE ST2110-40 SMPTE ST2022-7 RFC 4175 SMPTE ST2059

However, this type of transmission method has the following problems:

That is, in order to handle RTP packetized material in the master transmission system, a method is adopted in which the transmitted RTP packets are converted into SDI by an IP gateway and then an effect device having an SDI interface is used. In this method, the start timing of the IP/SDI conversion process is specified by the PT, which is the value for the RTP timestamp stamped on the RTP packet by the RTP transmitter that transmits the RTP.

Since a 90 kHz clock is used for RTP timestamps (Non-Patent Document 5), PTs are usually specified in 90 kHz units. Therefore, phase adjustment can only be done in larger units compared to conventional SDI phase adjustment (74 MHz for HD). Since the range of AVDL is usually about one line (1 line is 29.7 μsec for HD), phase adjustment in units of 90 kHz (= 11.1 μsec) is a large setting unit, and it is not easy to perform phase adjustment for each material input to the master transmission system.

In addition, because IP gateways are synchronized by PTP (Precision Time Protocol), the SDI output from the IP gateway is affected by fluctuations in PTP synchronization. Therefore, even if the phase falls within the AVDL range at a certain timing, it may fall outside the AVDL range due to the influence of fluctuations.

As such, conventional transmission methods that transmit RTP packets over IP networks do not take into account the phase constraints specific to master transmission systems. This increases the difficulty of setting the phase of the IP gateway output within the AVDL range of the effects device, resulting in increased design costs. In addition, it is not easy to set the phase of the IP gateway output while taking into account fluctuations in PTP synchronization, which could lead to unstable time synchronization during operation and disruption of broadcasts.

The problem that the present invention aims to solve is to provide a transmission system and transmission method, as well as an IP gateway and effect device applied to the transmission system, that can automatically discover optimal phase setting parameters when constructing the system, thereby suppressing increases in system design costs, and that can mitigate the adverse effects on broadcasting when PTP synchronization failure occurs by setting the phase while taking into account fluctuations in PTP synchronization.

The IP gateway of the embodiment is applied to a transmission system and includes an RTP receiving unit that receives RTP (Real-time Transport Protocol) packets transmitted via IP (Internet Protocol) and acquires header information from the RTP header of the RTP packet, a time synchronization unit that performs time synchronization based on PTP (Precision Time Protocol) by transmitting and receiving PTP messages, a device setting unit that receives target phase information, a timing derivation unit that acquires timing information from the header information and derives the start timing of a process to convert the RTP packet to SDI (Serial Digital Interface) based on the timing information, device time information, and target phase information, and an IP/SDI conversion unit that starts processing according to the derived start timing.

FIG. 1 is a schematic configuration diagram showing an example of a master transmission system to which the transmission method of the first embodiment is applied. FIG. 2 is a block diagram showing an example of the configuration of the IP gateway 23 and the effect device 26 which realize a master transmission system to which the transmission method of the first embodiment is applied. FIG. 3 is a flow chart showing an example of the operation of the IP gateway 23 and the effect device 26 shown in FIG. FIG. 4 is a data configuration diagram showing an example of an RTP header. FIG. 5 is a flowchart showing the flow of processing by the timing derivation unit 34. FIG. 6 is a diagram showing the relationship among transmission time, IP/SDI conversion latency, and target phase timing. FIG. 7 is a block diagram showing an example of a configuration including an IP gateway 23a and an effect device 26 that realizes a master transmission system to which the transmission method of the first modified example of the first embodiment is applied. FIG. 8 is a flow chart showing an example of the operation of the IP gateway 23a and the effect device 26 shown in FIG. FIG. 9 is a data structure diagram showing an example of an RTP payload header. FIG. 10 is a flowchart showing the flow of processing by the phase difference detection unit 37. FIG. 11 is a block diagram showing a configuration example including an IP gateway 23 and an effect device 26a that implements a master transmission system to which the transmission method of the second modification of the first embodiment is applied. FIG. 12 is a flowchart showing an example of the operation of the IP gateway 23 shown in FIG. FIG. 13 is a flowchart showing an example of the operation of the phase difference detection section 44 of the effect device 26a shown in FIG. FIG. 14 is a diagram showing detailed relationships between the timing of transmission times, IP/SDI conversion latencies, and target phases. FIG. 15 is a block diagram showing an example of a configuration including an IP gateway 23 and an effect device 26 that realizes a master transmission system to which the transmission method of the second embodiment is applied. FIG. 16 is a flowchart illustrating an example of the operation of the master transmission system to which the transmission method of the second embodiment is applied. FIG. 17 is a diagram showing the relationship among the transmission time, IP/SDI conversion latency, and target phase timing considered in the master transmission system to which the transmission method of the second embodiment is applied. FIG. 18 is a block diagram illustrating a configuration example including an IP gateway 23 and an effect device 26b that implements a master transmission system to which the transmission method of Modification 1 of the second embodiment is applied. FIG. 19 is a flowchart showing an example of the operation of the IP gateway 23 shown in FIG. FIG. 20 is a flowchart showing an example of the operation of the effect device 26b shown in FIG. 18. FIG. 21 is a block diagram illustrating a configuration example including an IP gateway 23 and an effect device 26 that implements a master transmission system to which the transmission method of Modification 2 of the second embodiment is applied. FIG. 22 is a flowchart showing an example of the operation of the measuring device 29 shown in FIG. FIG. 23 is a block diagram showing an example of a configuration including an IP gateway 23 and an effect device 26a that realizes a master transmission system to which the transmission method of the third embodiment is applied. FIG. 24 is a flowchart showing an example of the operation of the IP gateway 23 shown in FIG. FIG. 25 is a flowchart showing an example of the operation of the master transmission system according to the modified example of the third embodiment.

EMBODIMENT OF THE INVENTION Below, each embodiment of this invention is described with reference to drawings. The drawings are schematic or conceptual, and the relationship between the thickness and width of each part, the size ratio between parts, etc. are not necessarily the same as those in reality. Furthermore, even when the same part is shown, the dimensions and ratios may be shown differently depending on the drawing. In the specification of this application and each figure, the same elements as those described above with respect to the existing figures are given the same reference numerals, and detailed explanations are omitted as appropriate.

[First embodiment]
A master transmission system to which the transmission method of the first embodiment is applied will be described.

Figure 1 is a schematic diagram showing an example of a master transmission system to which the transmission method of the first embodiment is applied.

That is, the master transmission system 10 to which the transmission method of the first embodiment is applied has two systems, an active system 20A and a backup system 20B, which have the same configuration. Normally, the active system 20A operates, but even if the active system 20A is inoperable, the backup system 20B operates, thereby ensuring redundancy.

The following explains the configuration of the two systems, using the current system 20A as an example.

The active system 20A includes a control device 21, a synchronization signal generator 22, an IP gateway 23, a frame synchronization section (hereinafter abbreviated to "FS" for its English equivalent, Frame Synchronizer) 24, a switcher 25, an effects device 26, an encoding device 27, and a multiplexing device 28.

One control device 21, one synchronizing signal generator 22, one switcher 25, and one multiplexing device 28 exists in the active system 20A, but one IP gateway 23, FS 24, effect device 26, and encoding device 27 exist in the active system 20A. There are many.

Materials are input to the master transmission system 10 from the studio α, the line center β, the server system γ, etc. If the input material is IP, the IP gateway 23 receives it, and if the input material is SDI, it is received by the FS 24 or the switcher. 25 receives.

If the input material received via IP is frequency synchronized, the IP gateway 23 outputs this input material to the switcher 25. An example of such an IP gateway 23 is shown as IP gateway ₂₃₁ in FIG.

On the other hand, if the input material received via IP is frequency asynchronous, the IP gateway 23 outputs it to the FS 24 . The FS 24 performs synchronous coupling for system synchronization on input materials. Examples of such an IP gateway 23 and FS 24 are shown in FIG. 1 as IP gateway 23 _n and FS 24 _n .

If the input material is frequency-synchronized SDI, it is received by switcher 25.

The frequency asynchronous SDI input material is received by FS 24, which performs synchronous coupling to the input SDI input material for system synchronization. An example of such a FS 24 is shown in _FIG .

The switcher 25 automatically switches between the frequency-synchronized input materials in this way according to a transmission schedule. In addition, many effect devices 26 are connected to the switcher 25, and the switched input materials are output to the corresponding effect devices 26, respectively.

The effect devices 26 (e.g., effect devices ₂₆₁₁ , ..., _26n1 , 26 _(n+1)1 , ..., _26m1 ) connected to the switcher 25 are configured in a multi-stage configuration with one or more effect devices ₂₆ directly connected downstream. For example, effect devices ₂₆₁₂ , ..., _261N1 are connected downstream of effect device 2611. Each of these multi-stage effect devices 26 performs the above-mentioned effect processing on the frequency-synchronized input material, and each of the final-stage effect devices _261N1 , ..., _26nN2 , 26 _(n+1)N3 , ..., _26mN4 outputs the effect-processed input material to the corresponding encoding devices ₂₇₁ , ..., _27n , 27n ₊₁ , ..., _27m .

Each encoding device 27 performs encoding processing on the input material output from the corresponding effect device 26, and outputs the encoded input material to the multiplexing device 28.

The multiplexing device 28 performs multiplexing processing on the input material output from each encoding device 27, and outputs the multiplexed input material to the transmission system 50.

The technical feature of the master transmission system to which the transmission method of this embodiment is applied is that after the transmitted RTP packet is converted into SDI by the IP gateway 23, the effect processing is performed by the effect device 26 having an SDI interface. be.

Therefore, the following describes the IP gateway 23 and effect device 26 that realize the master transmission system to which the transmission method of this embodiment is applied.

Figure 2 is a block diagram showing an example configuration of an IP gateway 23 and an effect device 26 that realize a master transmission system to which the transmission method of the first embodiment is applied.

The IP gateway 23 and effect device 26 shown in FIG. 2 correspond to the IP gateway 23 ₁ and effect device 26 ₁₁ in FIG. 1, but will be described below as the IP gateway 23 and effect device 26. In FIG. 2, the studio α, the line center β, and the server system γ, which transmit RTP packets to the IP gateway 23 via IP, are collectively shown as an RTP transmitter 60. Further, in FIG. 2, the switcher 25 is omitted.

A synchronization signal generator 22 is commonly connected to the IP gateway 23 and the effect device 26, and thereby the synchronization signal generator 22 synchronizes the IP gateway 23 and the effect device 26.

FIG. 3 is a flowchart showing an example of the operation of the IP gateway 23 and the effect device 26 shown in FIG.

The step numbers shown in FIG. 3 are also shown in FIG.

The IP gateway 23 includes an RTP receiving section 31, an IP/SDI converting section 32, a device setting section 33, a timing deriving section 34, and a time synchronizing section 35.

The effect device 26 includes an AVDL unit 41, a frame counter 42, and a signal processing unit 43.

The RTP receiving unit 31 receives an RTP packet transmitted via IP from the RTP transmitter 60 (S1), outputs the received RTP packet to the IP/SDI conversion unit 32, and also acquires header information h from the RTP header of the RTP packet and outputs the acquired header information h to the timing derivation unit 34 (S2).

FIG. 4 is a data configuration diagram showing an example of an RTP header.

The synchronization signal generator 22 outputs a PTP message a to the time synchronization unit 35. It also outputs a BB (Black Burst) signal b to the frame counter 42 of the effect device 26.

The time synchronization unit 35 performs time synchronization based on PTP by transmitting and receiving the PTP message a to and from the synchronization signal generator 22, and outputs the time synchronized with the synchronization signal generator 22 to the timing derivation unit 34 (S3).

The control device 21 manages the phase of the entire master transmission system 10 and outputs target phase information c to be input to the AVDL section 41 of the effect device 26 to the device setting section 33 of the IP gateway 23.

The device setting section 33 receives the target phase information c output from the control device 21, and outputs the received target phase information c to the timing derivation section 34 (S4).

The timing derivation unit 34 acquires timing information t from the header information h, and determines the start timing PT of the IP/SDI conversion process based on the acquired timing information t, device time information d, and target phase information c. The derived PT is output to the IP/SDI converter 32 (S5). For this process, the timing derivation unit 34 specifically operates according to the flowchart in FIG. 5.

Figure 5 is a flowchart showing the processing flow of the timing derivation unit 34.

The timing derivation unit 34 extracts, as timing information, the "M" bit indicating the end of the frame and the "Time stamp" stamped by the RTP transmitter 60 at the time of transmission from the RTP header whose data structure is shown in FIG. Stamp” (S11). Then, the timing derivation unit 34 obtains the transmission time at which the RTP packet was transmitted from the obtained "M" bit and "Time Stamp" (S12). Furthermore, the timing derivation unit 34 takes into consideration the latency of the IP/SDI conversion unit 32 (hereinafter referred to as “IP/SDI conversion latency”) so that the output of the IP/SDI conversion unit 32 has the target phase. PT is set and output to the IP/SDI converter 32 (S13).

Figure 6 shows the timing relationship between transmission time, IP/SDI conversion latency, and target phase.

As shown in FIG. 6, the following relationship holds true.

PT=Ti+Ta-IP/SDI conversion latency,
Ti = Alignment point time - transmission time,
Ta = target phase time - alignment point time,
Here, the IP/SDI conversion latency is a value specific to the IP gateway 23, and the target phase is expressed by relative lines+pixels with respect to a reference point and is a value specific to the effect device 26. For a method of converting between time and phase, see Non-Patent Document 6.

The IP/SDI conversion unit 32 starts IP/SDI conversion of the RTP packets according to the PT output from the timing derivation unit 34, and outputs the resulting SDI to the AVDL unit 41 of the effect device 26 (S6).

The AVDL section 41 receives the SDI output from the IP/SDI conversion section 32, and outputs the received SDI to the signal processing section 43 with an appropriate phase as described later.

The frame counter 42 receives the BB signal b output from the synchronization signal generator 22, counts frames from the BB signal b, and outputs the count value e to the signal processing unit 43.

Since the signal processing section 43 performs processing according to this count value e, the AVDL section 41 inputs the SDI to the signal processing section 43 at an appropriate phase.

However, since the AVDL unit 41 has a memory of about one line, if the phase shift of the SDI input from the IP/SDI conversion unit 32 is small, the signal processing unit 43 can read and output the SDI at the desired phase.

As described above, according to the master transmission system 10 to which the transmission method of this embodiment is applied, the optimal IP/SDI conversion start timing PT can be found based on the timing information t, the device time information d, and the target phase information c. In this way, the optimal phase setting parameters can be automatically discovered, which suppresses increases in system design costs, and by setting the phase taking into account fluctuations in PTP synchronization, it is possible to mitigate the adverse effects on broadcasting when PTP synchronization fails.

(Modification 1 of the first embodiment)
Modification 1 of the first embodiment will be described. The explanation will be omitted for the same points as in the first embodiment, and only the different points will be explained.

FIG. 7 is a block diagram showing a configuration example including an IP gateway 23a and an effect device 26 that implements a master transmission system to which the transmission method of Modification 1 of the first embodiment is applied.

Figure 8 is a flowchart showing an example of the operation of the IP gateway 23a and the effect device 26 shown in Figure 7.

The step numbers shown in FIG. 8 are also shown in FIG.

The master transmission system to which the transmission method of this modified example is applied is characterized by the configuration of the IP gateway 23a, in which the RTP receiver 31 obtains the RTP payload header p from the RTP payload, rather than the RTP header. Even with this configuration, the same effects as those of the first embodiment are achieved.

Such an IP gateway 23a eliminates the timing derivation section 34 of the IP gateway 23 and includes a phase difference detection section 37 instead, and further includes a frame counter 36 between the phase difference detection section 37 and the time synchronization section 35. This is an additional configuration.

The RTP receiving unit 31 receives an RTP packet transmitted via IP from the RTP transmitter 60 (S1), outputs the RTP packet to the IP/SDI conversion unit 32, and also obtains the RTP payload header p from the RTP packet and outputs it to the phase difference detection unit 37 (S2A).

Figure 9 is a data structure diagram showing an example of an RTP payload header.

The RTP payload header p illustrated in FIG. 9 follows the RTP header illustrated in FIG. 4 in an RTP packet.

As described above, the time synchronization unit 35 performs time synchronization based on PTP by transmitting and receiving a PTP message a with the synchronization signal generator 22, and outputs the time synchronized with the synchronization signal generator 22 to the timing derivation unit 34 (S3).

The frame counter 36 generates a count value e from this device time information d, and outputs the count value e to the phase difference detection section 37 (S3A).

As described above, the device setting unit 33 acquires the target phase information c output from the control device 21 (S4). In this modified example, the device setting unit 33 then outputs the target phase information c to the phase difference detection unit 37.

Based on the RTP payload header p outputted from the RTP reception section 31, the count value e outputted from the frame counter 36, and the target phase information c outputted from the device setting section 33, the phase difference detection section 37, The start timing PT of the IP/SDI conversion process is derived and output to the IP/SDI conversion unit 32 (S5). For this process, the phase difference detection section 37 specifically operates according to the flowchart in FIG. 10.

FIG. 10 is a flowchart showing the process flow of the phase difference detection section 37.

The phase difference detection unit 37 obtains the field identifier "F", the line number "SRD Row Number", and the sample offset "SRD Offset" from the RTP payload header whose data structure is shown in FIG. 9 (S21), and obtains the count value. The phase of the received RTP packet with respect to e is determined (S22), and from the phase difference between the target phase and the received RTP packet, the relational expression "(IP/SDI conversion start timing) = (target phase) - (received RTP packet phase) - ( IP/SDI conversion latency) is used to calculate the start timing PT of the IP/SDI conversion process (S23). Then, the calculated start timing PT is output to the IP/SDI converter 32 (S5).

The IP/SDI conversion unit 32 starts IP/SDI conversion of the RTP packets according to the start timing PT output from the phase difference detection unit 37, and outputs the resulting SDI to the AVDL unit 41 of the effect device 26 (S6).

Even when SDI is input from the IP gateway 23a in this manner, the effect device 26 operates as described in the first embodiment.

According to the master transmission system to which the transmission method of this modified example is applied, the master transmission system 10 to which the transmission method of this modified example is applied in which the RTP receiving unit 31 obtains the RTP payload header p from the RTP payload instead of the RTP header can achieve the same effect as the first embodiment.

(Modification 2 of the First Embodiment)
Modification 2 of the first embodiment will be described. In the description, the points that are the same as in the first embodiment will be omitted, and only the points that are different will be described.

FIG. 11 is a block diagram showing a configuration example including an IP gateway 23 and an effect device 26a that implements a master transmission system to which the transmission method of the second modification of the first embodiment is applied.

Figure 12 is a flowchart showing an example of the operation of the IP gateway 23 shown in Figure 11.

FIG. 13 is a flowchart showing an example of the operation of the phase difference detection section 44 of the effect device 26a shown in FIG.

The master transmission system to which the transmission method of this modified example is applied is characterized by the configuration of the effect device 26a, in which a phase difference detection unit 44 is added to the effect device 26a, and when IP/SDI conversion is performed at an arbitrary PT by the IP gateway 23, the phase difference detection unit 44 measures the phase of the input SDI to the frame counter 42 of the effect device 26a, and feeds back the measurement result to the IP gateway 23, allowing the IP gateway 23 to derive the optimal PT.

The step numbers shown in Figures 12 and 13 are also shown in Figure 11.

Steps S1 to S3 have already been explained, and therefore will not be explained again.

After step S3, in the IP gateway 23, in step S3B, the IP/SDI conversion unit 32 performs IP/SDI conversion processing on the RTP packet output from the RTP reception unit 31 using an arbitrary PT, and The SDI obtained by the /SDI conversion process is output to the AVDL section 41 and the phase difference detection section 44 (S3B).

On the other hand, in the effect device 26a, the frame counter 42 receives the BB signal b output from the synchronization signal generator 22, generates a count value e from the BB signal b, and transfers the generated count value e to the signal processing unit 43 and It is output to the phase difference detection section 44 (S27).

The phase difference detection unit 44 receives the SDI output from the IP/SDI conversion unit 32 in step 3B, and determines the phase of the SDI with respect to the count value e output from the frame counter 42 in step S27 (S28).

The phase difference detection unit 44 further derives the phase difference f between this phase and the target phase of the effect device 26a that the phase difference detection unit 44 holds internally, and transmits it to the control device 21 (S29).

The control device 21 receives the transmitted phase difference f. As a result, the control device 21 manages the phase of the entire master transmission system 10. The control device 21 then outputs the phase difference f to the device setting unit 33 of the IP gateway 23. The device setting unit 33 receives this phase difference f and outputs the received phase difference f to the timing derivation unit 34 (S3C).

The timing derivation unit 34 receives the phase difference f, adds the phase difference f to PT, and outputs it to the IP/SDI conversion unit 32 (S3D).

In response to this, the IP/SDI conversion unit 32 performs IP/SDI conversion processing with the PT to which the phase difference f has been added as a new start timing, and outputs the SDI obtained as a result of the conversion processing to the effect device 26a. (S6).

The master transmission system to which the transmission method of this modified example is applied can update the phase difference f of the control device 21, thereby enabling optimization of the start timing PT of the IP/SDI conversion process performed by the IP/SDI conversion unit 32.

(Modification 3 of the first embodiment)
Modification 3 of the first embodiment will be described. In the description, the points that are the same as in the first embodiment will be omitted, and only the points that are different will be described.

The master sending system to which the sending method of this modified example is applied is characterized by the IP gateway 23, and in particular the timing derivation unit 34. The master sending system to which the sending method of this modified example is applied has the same configuration as the master sending system of the first embodiment, as shown in FIG. 2, and only the operation of the timing derivation unit 34 is different.

Specifically, in this modified example, the timing derivation unit 34 calculates the PT for each frame. This differs from the first embodiment, in which the timing derivation unit 34 calculates the PT only once at the start of IP/SDI conversion, on the premise that the time difference between the transmission time and the reference point (alignment point) is constant, as shown in FIG. 6.

In this modification, the timing derivation unit 34 calculates PT for each frame, thereby making it possible to achieve the following effects.

Figure 14 shows the detailed relationship between transmission time, IP/SDI conversion latency, and target phase timing.

Since the RTP timestamp is stamped in units of 90 kHz, it is conceivable that the transmission time Ti will fluctuate by a width of 90 kHz (11.1 μsec), as shown in FIG. 14. However, according to this modified example, the transmission time can be obtained for each frame in conjunction with the fluctuation, so it is possible to deal with the fluctuation of the transmission timestamp and calculate the optimal PT.

In addition, since the RTP timestamp is stamped based on the time information of the RTP transmitter 60, it is conceivable that the characteristics will change when the RTP transmitter 60 is switched. However, according to this modified example, the transmission time can be obtained for each frame in conjunction with the changes, so it is possible to calculate the optimal PT by dealing with changes in the characteristics of the transmission timestamp due to switching of the RTP transmitter 60, etc.

Second Embodiment
A master transmission system to which the transmission method of the second embodiment is applied will be described. In the description, the same points as in the first embodiment will be omitted and only the different points will be described.

Figure 15 is a block diagram showing an example configuration including an IP gateway 23 and an effect device 26 that realizes a master transmission system to which the transmission method of the second embodiment is applied.

The configurations of the IP gateway 23 and the effect device 26 that implement the master transmission system to which the transmission method of the second embodiment is applied are the same as those shown in FIG. 2 already shown.

However, this embodiment is characterized by the IP gateway 23, particularly the device setting section 33, the timing derivation section 34, and the time synchronization section 35. As mentioned above, the time synchronization unit 35 performs time synchronization based on PTP. However, since the time synchronization accuracy of PTP is 1 μsec, the timing of the SDI output from the IP gateway 23 will fluctuate with the accuracy of PTP. Therefore, even if the phase can be set within the AVDL range at a certain time, it may deviate from the AVDL range due to PTP fluctuations. Therefore, in the master transmission system to which the transmission method of this embodiment is applied, PT is set in consideration of PTP fluctuations.

FIG. 16 is a flowchart illustrating an example of the operation of the master transmission system to which the transmission method of the second embodiment is applied.

The step numbers shown in FIG. 16 are also shown in FIG.

The flowchart shown in FIG. 16 replaces step S3 and part of step S4 in the flowchart shown in FIG. 3 with step S2B and step S2C, respectively. Therefore, steps S2B and S2C will be described below.

The time synchronization unit 35 transmits and receives a PTP message a to and from the synchronization signal generator 22, and each time compares the time of the synchronization signal generator 22 with the time of the time synchronization unit 35 to obtain the magnitude of the time fluctuation, i.e., fluctuation information m, and outputs it together with the device time information d to the timing derivation unit 34 (S2B).

The magnitude of the fluctuation is considered to vary depending on environmental factors such as the synchronization signal generator 22 and the network. Therefore, the time synchronization unit 35 determines the magnitude of fluctuation for each system.

The timing derivation unit 34 derives the PT based on the magnitude of the fluctuation obtained from the fluctuation information m, the target phase range (upper limit, lower limit) output from the device setting unit 33 in step S4, and the header information h from the RTP receiving unit 31 (S2C).

Figure 17 shows the timing relationship between the transmission time, IP/SDI conversion latency, and target phase taken into account in a master transmission system to which the transmission method of the second embodiment is applied.

The timing derivation unit 34 further calculates the following relationship as shown in FIG.
PT≦Ta2−Ti−IP/SDI conversion latency−fluctuation information, and PT≧Ta1−Ti−IP/SDI conversion latency+fluctuation information,
The PT is derived so as to satisfy the above, and the derived PT is sent to the IP/SDI conversion unit 32 (S5).

As described above, according to the master transmission system to which the transmission method of the second embodiment is applied, the IP gateway 23 takes into account the magnitude of fluctuation to give a width to the target phase and eliminate the presence of fluctuation. PT can be set so that it falls within the range of the target phase.

(Variation 1 of the second embodiment)
A first modified example of the second embodiment will be described. In the description, the points that are the same as those in the second embodiment will be omitted, and only the points that are different will be described.

FIG. 18 is a block diagram showing a configuration example including an IP gateway 23 and an effect device 26b that implements a master transmission system to which the transmission method of Modification 1 of the second embodiment is applied.

FIG. 19 is a flowchart showing an example of the operation of the IP gateway 23 shown in FIG. 18.

FIG. 20 is a flowchart showing an example of the operation of the effect device 26b shown in FIG. 18.

The step numbers shown in Figures 19 and 20 are also shown in Figure 18.

The flowchart shown in FIG. 19 is obtained by replacing step S4 in the flowchart shown in FIG. 3 with step S3E and step S2C, which has already been described. Also, the flowchart shown in FIG. 20 is obtained by replacing steps S28 and S29 in the flowchart shown in FIG. 13 with steps S28A and S29A.

Therefore, the following mainly describes steps S3E, S28A, and S29A.

That is, the master transmission system to which the transmission method of this modified example is applied is characterized by the effect device 26b and the control device 21, and a fluctuation measurement unit 45 is added to the effect device 26b. The fluctuation measurement unit 45 receives the SDI output from the IP/SDI conversion unit 32, measures the phase fluctuation of the received SDI relative to the count value e acquired in step S27 (S28A), and transmits fluctuation information m including the magnitude of the measured fluctuation to the control device 21 (S29A).

The control device 21 receives the fluctuation information m sent from the fluctuation measurement unit 45. Then, in addition to the target phase information c, it also outputs the fluctuation information m to the device setting unit 33.

The device setting unit 33 receives the target phase information c and fluctuation information m output from the control device 21, and outputs the target phase information c and fluctuation information m to the timing derivation unit 34 (S3E).

The timing derivation unit 34 derives a PT based on the target phase information c, the fluctuation information m, the header information h, and the device time information d so that the output phase of the IP gateway 23 does not exceed the target phase range, and outputs the PT to the IP/SDI conversion unit 32.

According to the master transmission system to which the transmission method of this modification is applied, even when there is phase fluctuation, the optimum start timing PT of the IP/SDI conversion process performed by the IP/SDI conversion unit 32 can be adjusted. This makes it possible to achieve

(Modification 2 of the second embodiment)
Modification 2 of the second embodiment will be described. The explanation will be omitted for the same points as in the second embodiment, and only the different points will be explained.

FIG. 21 is a block diagram illustrating a configuration example including an IP gateway 23 and an effect device 26 that implements a master transmission system to which the transmission method of Modification 2 of the second embodiment is applied.

In the master transmission system to which the transmission method of this modification is applied, the fluctuation measurement unit 45 provided inside the effect device 26b in FIG. It is distinctive in that it is equipped inside.

A flowchart showing an example of the operation of the IP gateway 23 shown in FIG. 21 is the same as that in FIG. 19.

FIG. 22 is a flowchart showing an example of the operation of the measuring device 29 shown in FIG.

The step numbers shown in Figures 19 and 22 are also shown in Figure 21.

The flowchart shown in FIG. 22 replaces steps S27 and S28A of the flowchart shown in FIG. 20 with steps S27A and S28B.

Therefore, the following mainly describes steps S27A and S28B.

The fluctuation measurement unit 45 receives the BB signal b output from the synchronization signal generator 22 (S27A). The fluctuation measurement unit 45 also receives the SDI output from the IP/SDI conversion unit 32 in step S6, monitors the phase of the SDI relative to the BB signal b, measures the magnitude of the phase fluctuation (S28B), and outputs fluctuation information m including the measured magnitude of the fluctuation to the control device 21 (S29A).

In this way, the effect achieved by the configuration with the addition of the fluctuation measurement unit 45 is the same as that achieved by variant 1 of the second embodiment, but in this variant, the fluctuation measurement unit 45 is provided outside the effect device 26, so it can be realized even if the fluctuation measurement unit 45 cannot be built into the effect device 26b as shown in Figure 18.

[Third embodiment]
A master transmission system to which the transmission method of the third embodiment is applied will be described. The explanation will be omitted for the same points as in the first and second embodiments, and only the different points will be explained.

Figure 23 is a block diagram showing an example configuration including an IP gateway 23 and an effect device 26a that realizes a master transmission system to which the transmission method of the third embodiment is applied.

The master transmission system to which the transmission method of the third embodiment is applied is intended to cope with a case where the PTP synchronization environment is unstable and the PTP accuracy exceeds 1 μsec.

An example of an event where the PTP synchronization environment is unstable and the PTP accuracy exceeds 1 μsec is that the communication between the synchronization signal generator 22 and the IP gateway 23 is unstable, and the time synchronization unit 35 of the IP gateway 23 holds over. including cases. During holdover, a time lag occurs in the synchronization signal generator 22, and the synchronization with the BB signal b becomes out of sync. At this time, there is a possibility that the AVDL pull-in range will be exceeded.

The configuration of the IP gateway 23 and effect device 26a in FIG. 23 is the same as the configuration of the IP gateway 23 and effect device 26a in FIG. 11. However, as mentioned above, communication between the synchronization signal generator 22 and the IP gateway 23 is unstable, and the time synchronization unit 35 of the IP gateway 23 is in holdover. In FIG. 23, the holdover is indicated by a dotted line.

Figure 24 is a flowchart showing an example of the operation of the IP gateway 23 shown in Figure 23.

The step numbers in FIG. 24 are also shown in FIG. 23. Explanation of the already mentioned step numbers will be omitted.

Among the step numbers shown in FIG. 24, step S5A, which has not been mentioned previously, corresponds to a characteristic process in this embodiment. Therefore, below, mainly step S5A will be explained.

If holdover occurs during operation of the IP gateway 23 (S5A: Yes), steps S3C and S3D described above are performed.

That is, in step S3C, the control device 21 receives the phase difference f transmitted from the phase difference detection unit 44 and outputs the phase difference f to the device setting unit 33, which receives this phase difference f and outputs the received phase difference f to the timing derivation unit 34 (S3C).

Next, in step S3D, the timing derivation unit 34 receives the phase difference f, updates the PT by adding the phase difference f, and outputs the updated PT to the IP/SDI conversion unit 32 (S3D).

In response, the IP/SDI conversion unit 32 performs IP/SDI conversion processing using the updated PT as a new start timing, and outputs the SDI obtained as a result of the conversion processing to the effect device 26a (S6). .

Thereafter, the processing of steps S27 to S29 described above is performed in the effect device 26a, the phase difference f is fed back to the control device 21, and the operation shown in FIG. 24 is repeated, thereby updating the phase difference f of the control device 21. By resetting the start timing PT of the IP/SDI conversion process performed by the IP/SDI conversion unit 32, it is possible to prevent the AVDL pull-in range from being exceeded and suppress the negative impact on broadcasting.

If holdover does not occur during operation (S5A: No), the process proceeds to step S6 after step S5. The process flow is the same as that shown in the flowchart in FIG. 3.

Next, as a modification of this embodiment, in order to have holdover tolerance, the amount of phase shift per unit time during holdover is measured at the time of system construction so that the AVDL range is not exceeded when holdover occurs. A method for setting the PT as shown in FIG. 25 will be explained using the flowchart of FIG.

In step S6, as described above, the IP/SDI conversion unit 32 of the IP gateway 23 executes IP/SDI conversion (S6), and the SDI is output to the AVDL unit 41 and phase difference detection unit 44 of the effect device 26a. Ru. As a result, the SDI is received by the phase difference detection section 44 (S32). Further, the time synchronization unit 35 of the IP gateway 23 is placed in a holdover state (S33).

Next, the phase shift per unit time of the received SDI is observed in the phase difference detection unit 44 (S34), and the observed phase shift is transmitted from the phase difference detection unit 44 to the control device 21 (S35).

Although several embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, substitutions, and modifications can be made without departing from the gist of the invention. These embodiments and their modifications are within the scope of the invention and its equivalents as set forth in the claims, as well as the scope and gist of the invention.

DESCRIPTION OF SYMBOLS 10... Master transmission system, 20A... Working system, 20B... Standby system, 21... Control device, 22... Synchronization signal generator, 23... Gateway, 24... Frame synchronization unit, 25... Switcher, 26... Effect device, 27... Encoding device, 28... Multiplexing device, 29... Measuring device, 31... RTP receiving section, 32... IP/SDI converting section, 33... Device setting section, 34 ...Timing derivation section, 35..Time synchronization section, 36..Frame counter, 37..Phase difference detection section, 41..AVDL section, 42..Frame counter, 43..Signal processing section, 44.. Phase difference detection unit, 45... Fluctuation measurement unit, 50... Transmission system, 60... RTP transmitter, a... PTP message, b... BB signal, c... Target phase information, d... Device time information, e...Count value, f...Phase difference, h...Header information, m...Fluctuation information, p...Payload header, PT...Start timing, t...Timing information, α...Studio, β... Line center, γ...server system.

Claims (15)

An IP gateway applied to a transmission system,
an RTP receiving unit that receives an RTP (Real-time Transport Protocol) packet transmitted by IP (Internet Protocol) and obtains header information from an RTP header of the RTP packet;
a time synchronization unit that performs time synchronization based on PTP (Precision Time Protocol) by transmitting and receiving PTP messages;
a device setting unit that receives the output target phase information;
a timing derivation unit that acquires timing information from the header information and derives a start timing of processing for converting the RTP packet to SDI (Serial Digital Interface) based on the timing information, device time information, and target phase information; and,
An IP gateway, comprising: an IP/SDI conversion unit that starts the processing according to the derived start timing. The IP gateway of claim 1, wherein the target phase information includes lines and pixels relative to a reference point. The target phase information includes fluctuation information,
2. The IP gateway according to claim 1, wherein the fluctuation information includes a magnitude of time fluctuation obtained based on a comparison between a time of a synchronization signal generator that generates a synchronization signal and a time of the time synchronizer. The IP gateway according to claim 1, wherein the target phase information includes a phase difference between a phase with respect to the SDI count value and a designated target phase. If the time synchronization unit is unable to receive the PTP message due to holdover, the timing derivation unit updates the start timing by adding the phase difference to the start timing,
The IP gateway according to claim 4, wherein the IP/SDI converter starts the process according to the updated start timing. The IP gateway according to any one of claims 1 to 5, wherein the timing derivation unit derives the start timing for each frame. The time synchronization unit compares the time indicated by the device time information and the time owned by the time synchronization unit, and outputs a magnitude of fluctuation as a comparison result to the timing derivation unit,
The IP gateway according to claim 6, wherein the timing derivation unit acquires target phase range information based on the magnitude of the fluctuation. An IP gateway applied to a transmission system, comprising:
an RTP receiving unit that receives an RTP (Real-time Transport Protocol) packet transmitted via an IP (Internet Protocol) and obtains an RTP payload header from the RTP packet;
a time synchronization unit that performs time synchronization based on a Precision Time Protocol (PTP) by transmitting and receiving a PTP message;
a frame counter that counts frames based on device time information and outputs a count value;
A device setting unit that receives the output target phase information;
a phase difference detection unit that derives a start timing of a process of converting the RTP packet into an SDI (Serial Digital Interface) based on the RTP payload header, the count value, and the target phase information;
and an IP/SDI conversion unit that starts the process in accordance with the derived start timing. An effect device applied to a master playout system, comprising:
an AVDL unit that receives the SDI converted by the IP/SDI conversion unit of the IP gateway according to claim 1 and outputs the SDI with an appropriate phase;
a frame counter that receives the output black burst signal, counts frames from the black burst signal, and outputs a count value;
a signal processing unit that processes the SDI output by the AVDL unit in accordance with the count value output by the frame counter. A phase difference detection unit is further provided,
the AVDL unit and the phase difference detection unit receive the SDI converted at an arbitrary start timing by the IP/SDI conversion unit,
the frame counter outputs the count value to the phase difference detection unit;
10. The effect device according to claim 9, wherein the phase difference detection unit determines a phase of the received SDI with respect to the count value, and derives a phase difference between the phase and a target phase of the effect device held by the phase difference detection unit. A fluctuation measuring unit is further provided,
the AVDL unit and the fluctuation measurement unit receive the SDI converted by the IP/SDI conversion unit,
The frame counter outputs the count value to the fluctuation measurement unit,
the fluctuation measurement unit observes a phase shift per unit time of the SDI and outputs the observed phase shift;
The effect device of claim 9 , wherein the magnitude of the phase shift is included in fluctuation information. An IP gateway according to claim 1;
An effect device according to claim 9;
A control device that outputs the target phase information;
a synchronization signal generator that outputs the PTP message and the black burst signal. An IP gateway according to claim 7;
An effect device according to claim 9;
A control device that outputs the target phase information;
a synchronization signal generator that outputs the PTP message and the black burst signal. The IP gateway according to claim 5;
The effect device according to claim 10;
a control device that outputs the target phase information;
a synchronization signal generator that outputs the PTP message and the black burst signal,
The phase difference detection unit has the specified target phase, and transmits the phase difference between the phase of the SDI with respect to the count value and the specified target phase to the control device,
The control device receives the transmitted phase difference and outputs the phase difference to the device setting section,
The device setting section outputs the phase difference to the timing derivation section. A delivery method implemented by a delivery system according to claim 12.