JP4542829B2 - Dual automatic switching device - Google Patents

Description

The present invention relates to a dual-system automatic switching device for automatically switching a transmitter to an active system and a standby system, and more particularly to a dual-system automatic switching device suitable for transmission equipment for terrestrial digital television broadcasting. .

In transmission facilities with high publicity, such as for broadcasting, it is customary that at least a transmission system is duplicated, and that one is a working system and the other is a standby system so that high reliability can be obtained. In this case, a device for automatically switching between the active system and the standby system, that is, a so-called dual system automatic switching device is required (see, for example, Patent Document 1).

Here, FIG. 3 shows an example of a terrestrial digital television transmitter equipped with the prior art of such a dual-system automatic switching device. Two oscillators 1 and 2 and two OFDM modulators 3 are also shown. 4 and also two transmitters 5 and 6, and one of the two transmitters is, for example, an active system X and the other is a standby system Y. Note that OFDM is orthogonal frequency division modulation.

  First, the oscillators 1 and 2 generate a sine wave signal having a predetermined frequency. The sine wave signal is extracted by selecting one of the working system X and the standby system Y by the oscillation switching unit 7 and supplied to each of the OFDM modulators 3 and 4 via the oscillation abnormality detecting unit 8. Used as a modulation reference signal REF.

  At this time, an input signal for television broadcasting is input to each of the OFDM modulators 3 and 4. Therefore, this input signal is OFDM-modulated by each OFDM modulator 3, 4, and the OFDM signal output from each OFDM modulator 3, 4 is supplied to the input switching unit 10. In the input switching unit 10, one of the working system X and the standby system Y is also selected and supplied to the transmitters 5 and 6.

  Therefore, the transmitters 5 and 6 perform frequency conversion on the OFDM signal input as described above as necessary, and amplify the power to a predetermined level. Then, each transmission output signal is supplied to the output switching unit 13 where one of the working system X and the standby system Y is selected and output to a transmission system such as an antenna.

  At this time, first, the oscillation abnormality detection unit 8 monitors the level of the reference signal REF selected by the oscillation switching unit 7, and an abnormality is detected when the level is equal to or less than a predetermined threshold for determination. Then, the oscillation abnormality detection signal a is generated, and then the input abnormality detection unit 11 monitors the level of the OFDM signal selected by the input switching unit 10 and the level is equal to or lower than a predetermined threshold for determination. When an abnormality is detected, an input abnormality detection signal c is generated, and the output abnormality detection unit 14 monitors the level of the transmission output signal selected by the output switching unit 14, and the level is set in advance. The output abnormality detection signal e is generated when an abnormality is detected when the value is equal to or less than the threshold for determination.

  Next, the operation of each of the switching units 7, 10, 13 will be described. In this prior art, these are operated, and therefore delay timers 9, 12, 15 are provided as shown in the figure.

  First, the oscillation switching unit 7 is switched by the timer signal b output from the delay timer 9. The delay timer 9 operates using the oscillation abnormality detection signal a output from the oscillation abnormality detection unit 8 as a trigger. After the delay time D1 has elapsed from the time when the oscillation abnormality detection signal a is input, the delay timer 9 is set to a low level. Generates a timer signal b that goes high.

  At this time, the oscillation switching unit 7 selects the output of the oscillator 1 of the working system X when the timer signal b is at the low level, that is, normally, but when the timer signal b becomes the high level, The output is switched to the output of the oscillator 2 of the system Y.

  Next, the input switching unit 10 is switched by the timer signal d output from the delay timer 12. The delay timer 12 operates using the input abnormality detection signal c output from the input abnormality detection unit 11 as a trigger, and after the delay time D2 has elapsed from the time when the abnormality detection signal d is input, the level is high. A timer signal d which becomes a level is generated.

  At this time, the input switching unit 10 selects the output of the OFDM modulator 3 of the working system X when the timer signal d is at the low level, that is, normally, but the timer signal d is at the high level. Then, the output is switched to the output of the OFDM modulator 4 of the standby system Y.

  The output switching unit 13 is switched by the timer signal f output from the delay timer 15. The delay timer 15 operates using the output abnormality detection signal e output from the output abnormality detection unit 14 as a trigger. After the delay time D3 has elapsed from the time when the output abnormality detection signal e is input, the level of the delay timer 15 increases. A timer signal f that goes high is generated.

  At this time, the input switching unit 10 selects the output of the transmitter 5 of the working system X when the timer signal f is at a low level, that is, normally, but the timer signal f is at a high level. Then, the output is switched to the output of the transmitter 6 of the standby system Y.

  Next, the operation of this prior art will be described. First, the delay times D1, D2, and D3 of the delay timers 9, 12, and 15 are set to D1 <D2 <D3. At this time, the delay time D1 is set to a time necessary for reliably obtaining the abnormality detection by the oscillation abnormality detection unit 8, the delay time D2 is set to (D1 + τ), and the delay time D3 is set to (D2 + τ). = D1 + 2τ). Here, τ is a margin time, and details will be described later.

  First, FIG. 4 shows an operation in the case where an abnormality occurs only in the active system X oscillator 1 at a certain time T1, in which case the oscillation abnormality detection signal a of the oscillation abnormality detection unit 8 is high at the time T1. After that, the timer signal b becomes high level at time T2 when the delay time D1 elapses. As a result, the current system X is switched to the standby Y oscillator 2 at time T2.

  At this time, since an abnormality has occurred in the oscillator 1 of the working system X at time T1, the supply of the reference signal REF to the OFDM modulators 3 and 4 is also interrupted, so that the input abnormality detection signal c of the input abnormality detector 11 is also high. Further, since the supply of the modulation signal from the OFDM modulators 3 and 4 to the transmitters 5 and 6 is interrupted, the output abnormality detection signal f of the output abnormality detection unit 14 also becomes a high level. Shiu.

  However, in this case, the delay times D2 and D3 of the delay timers 12 and 15 are set in the relationship of D1 <D2 <D3 as described above with respect to the delay time D1 of the delay timer 9, At time T2, the timer signal b becomes high level, and the timer signal d of the delay timer 12 and the timer signal e of the delay timer 15 remain low even after switching from the active X oscillator 1 to the standby oscillator 2. It stays.

  Then, after time T1, the switching to the standby Y oscillator 2 occurs at time T3 when the delay time D2 of the delay timer 12 elapses, so that the abnormality detection signal d of the input abnormality detection unit 11 remains at the low level also after this time T3. Since the output abnormality detection signal e of the output abnormality detection unit 14 remains at the low level even at time T4 after the delay time D3 has elapsed, it is automatically removed from the active system with the minimum switching operation of only the oscillation switching unit 7. It can be switched to a standby system.

  Next, FIG. 5 shows a case where an abnormality occurs only in the OFDM modulator 3 of the working system X at time T1, and in this case, the input abnormality detection signal c of the input abnormality detection unit 11 is at a high level at time T1. Stand up to. Thereafter, at the time T3 when the delay time D2 elapses, the timer signal d becomes high level, and the OFDM modulator 3 of the working system X is switched to the OFDM modulator 4 of the standby system Y.

  At this time, since an abnormality has occurred in the OFDM modulator 3 of the working system X at time T1, the supply of the modulation signal to the transmitters 5 and 6 is interrupted, so the output abnormality detection signal e of the output abnormality detection unit 14 is also high. Become a level.

  However, in this case, since the delay time D3 of the delay timer 15 is set to the relationship of D2 <D3 as described above with respect to the delay time D2 of the delay timer 12, the timer signal d is set at time T3. Since the delay time D3 has not yet elapsed even after switching from the active system X OFDM modulator 3 to the standby system Y OFDM modulator 4, the timer signal f of the delay timer 15 remains unchanged. Remains at a low level.

  After the time T1, when the delay time D3 elapses and the time T4 is reached, the output abnormality detection signal e also returns to the low level because the switching to the OFDM modulator 4 of the standby system Y is performed. As a result, the timer signal f remains at the low level, and therefore, it is possible to automatically switch from the active system to the standby system with the minimum switching operation of only the input switching unit 11.

  Further, FIG. 6 shows a case where an abnormality has occurred only at the transmitter X of the working system X at time T1, and in this case, the output abnormality detection signal e of the output abnormality detection unit 14 rises to a high level at time T1. . Thereafter, at time T3 when the delay time D3 elapses, the timer signal f becomes high level, and the active X transmitter 5 is switched to the standby Y transmitter 6. As a result, only the output switching unit 14 is switched. It is possible to automatically switch from the active system to the standby system with the minimum switching operation.

Here, the above-described margin time τ is a time for delaying the switching of the subsequent device until the switching of the previous step is surely obtained in the automatic switching, and accordingly, D2 = D1 + τ and D3 = D2 + τ = D1 + 2τ. The relationship is established and, as described above, D1 <D2 <D3.
JP-A-10-290206

  In the above prior art, in the transmission device of the method of switching to the active system and the standby system by dividing into an oscillator, a modulator, and a transmitter, no consideration is given to shortening the switching time, and even when an abnormality occurs only in the subsequent device There was a problem that switching time could not be shortened.

  In the prior art, as apparent from FIGS. 4 to 6, in the case of an abnormality occurring in the preceding oscillators 1 and 2 in FIG. 4, switching from the active system to the standby system can be obtained only by the delay of time D1. However, in the case of the OFDM modulators 3 and 4 in the middle stage, as shown in FIG. 5, the time D2 (= D1 + τ) has elapsed, and in the case of the transmitters 5 and 6 in the subsequent stages, As shown in FIG. 6, it is found that the time D3 (= D1 + 2τ) has elapsed, and the time delay in switching from the active system to the standby system increases in the later stage.

  The present invention has been made in view of such a state of the art, and its purpose is to cope with any abnormality in the oscillation unit, the modulation unit, and the transmission unit when the switching time of the transmission device from the active system to the standby system is exceeded. Is to provide a double-system automatic switching device that is also the same.

The object is to provide two oscillation units, an oscillation switching unit that switches these oscillation units to a working system and a standby system, two modulation units that are supplied with signals from the oscillation unit selected by the oscillation switching unit, An input switching unit that switches these modulation units to the active system and the standby system, two transmission units to which signals are supplied from the modulation unit selected by the input switching unit, and these transmission units to the active system and the standby system An output switching unit for switching to the oscillation switching unit, an oscillation abnormality detection unit for detecting an abnormality from the output of the oscillation switching unit and generating an oscillation abnormality detection signal, and an abnormality from the output of the input switching unit for detecting an input abnormality detection signal. An input abnormality detection unit that generates, an output abnormality detection unit that detects an abnormality from the output of the output switching unit and generates an output abnormality detection signal, and delays the oscillation abnormality detection signal by time D1 and supplies the oscillation abnormality detection signal to the oscillation switching unit A first delay unit that performs the input abnormality detection signal Is delayed by time D2 (D2> D1) and supplied to the input switching unit, and the output abnormality detection signal is delayed by time D3 (D3> D2) and supplied to the output switching unit. The oscillation switching unit is switched between the active system and the standby system by an oscillation abnormality detection signal generated from the oscillation abnormality detection unit, and the input switching unit is generated from the input abnormality detection unit. The active system and the standby system are switched by the input abnormality detection signal, and the output switching unit is configured to switch between the active system and the standby system by the output abnormality detection signal generated from the output abnormality detection unit. In the dual automatic switching device of the apparatus, a controller for inputting the oscillation abnormality detection signal, the input abnormality detection signal, and the output abnormality detection signal is provided, and when only the input abnormality detection signal is input, the second of The operation of changing the time D2 set in the extension portion to the time D1 and changing the time D3 set in the third delay portion to the time D1 when only the output abnormality detection signal is input is described above. This is accomplished as executed by the controller.

  According to the present invention, even if an abnormality occurs in any of the transmitter systems, automatic switching can be obtained in the shortest time. Therefore, when switching between the active system and the standby system, the time during which transmission is disabled, the so-called stop time is reduced. It can be shortened.

  Hereinafter, the dual automatic switching device according to the present invention will be described in detail with reference to the illustrated embodiments.

  Here, FIG. 1 shows an embodiment of the present invention. In this figure, reference numeral 16 denotes a control unit, and other components are the same as those of the prior art described in FIG.

  Therefore, also in this embodiment, first, the oscillators 1 and 2 generate a sine wave signal of a predetermined frequency, and one of the working system X and the standby system Y is selected and extracted by the oscillation switching unit 7, and the oscillation abnormality detecting unit 8 Is supplied to each of the OFDM modulators 3 and 4 as a reference signal REF for OFDM modulation through the same as in the prior art.

  At this time, the input signals for television broadcasting are respectively input to the OFDM modulators 3 and 4, and the input signals are OFDM-modulated by the OFDM modulators 3 and 4, and the OFDM signal is input by the input switching unit 10. The current system X and the standby system Y are selected and supplied to the transmitters 5 and 6 in the same manner as in the prior art.

  Then, the OFDM signal is frequency-converted by the transmitters 5 and 6 and power amplified to a predetermined level, and then either the active system X or the standby system Y is selected by the output switching unit 13 to transmit a transmission system such as an antenna. This is also the same as the conventional technique.

  Furthermore, also in this embodiment, the point where the oscillation abnormality detection unit 8 generates the oscillation abnormality detection signal a according to the level of the reference signal REF selected by the oscillation switching unit 7 and the OFDM selected by the input switching unit 10 Depending on the signal level, the input abnormality detection unit 11 generates the input abnormality detection signal c, and the output abnormality detection unit 14 detects the output abnormality according to the level of the transmission output signal selected by the output switching unit 14. Each of the points generating the signal e is the same as in the prior art.

  In the embodiment of FIG. 1, the control unit 16 is provided, so that the input abnormality signal c is generated from the input abnormality detection unit 11 and the output abnormality signal e is generated from the output abnormality detection unit 14. In this case, a different operation is executed, which is different from the conventional technique shown in FIG.

  Here, the control unit 16 is constituted by a CPU (Central Processing Unit), that is, a so-called microcomputer, and as shown in the figure, an oscillation abnormality detection unit 8, an input abnormality detection unit 11, and an output abnormality detection unit 14. The oscillation abnormality detection signal a, the input abnormality detection signal c, and the output abnormality detection signal e are taken from each of them, and the delay time D2 of the delay timer 12 and the delay time D3 of the delay timer 15 are changed according to these calculation results. Work.

  At this time, the control unit 16 does not change anything about the delay time D1 set in the delay timer 9, and accordingly, the delay times D1, D2, and D3 is the same as in the prior art, and D1 <D2 <D3 is set.

  The delay time D1 at this time is set to a time necessary for reliably obtaining the abnormality detection by the oscillation abnormality detecting unit 8, and the delay time D2 is set to a time (D1 + τ) obtained by adding a margin time τ thereto. The delay time D3 is set to a time (D2 + τ = D1 + 2τ) obtained by adding a margin time τ to the delay time D3.

  Then, when the oscillation abnormality detection signal a is only generated from the oscillation abnormality detection unit 8, the control unit 16 does not do anything with respect to the delay time D2 of the delay timer 12 and the delay time D3 of the delay timer 15 as it is. To. Of course, the delay time D1 set in the delay timer 9 remains unchanged.

  Therefore, the operation at this time, that is, the operation in the case where an abnormality occurs only in the active system X oscillator 1 at a certain time T1, is the same as that in the above-described prior art and is as shown in FIG. In this case, the switching time from the active system X to the standby system Y is also the delay time D1 set in the delay timer 9.

  On the other hand, when the input abnormality detection signal c is generated from the input abnormality detection unit 11, the control unit 16 executes a process according to the flowchart of FIG. 2A and outputs an abnormality signal from the output abnormality detection unit 14. When e is generated, the process according to the flowchart of FIG. 2B is executed.

  First, when an input abnormality occurs, that is, when an input abnormality detection signal c is generated from the input abnormality detection unit 11, it is confirmed that no oscillation abnormality has occurred as shown in FIG. Step S1 is executed as a condition, and the delay time D2 of the delay timer 12 is changed to the delay time D1. If an oscillation abnormality has occurred here, that is, if an oscillation abnormality detection signal a has also occurred, step S2 is executed. Is executed, the delay time D2 of the delay timer 12 is not changed, and the delay time D2 remains unchanged.

  Next, when an output abnormality occurs, that is, when an output abnormality detection signal e is generated from the output abnormality detection unit 14, as shown in FIG. Step S3 is executed and the delay time D3 of the delay timer 15 is changed to the delay time D1. If an input abnormality has occurred, that is, if an input abnormality detection signal c has also occurred, step S4 is performed. When the delay time D3 of the delay timer 15 is set to the delay time D2 and an oscillation abnormality has occurred, that is, when the oscillation abnormality detection signal a has also occurred, step S4 is executed to delay the delay timer 15 The time D3 is not changed and is left as it is.

So, according to this embodiment,
(1) When only an oscillation error occurs
(2) When only an input error occurs
(3) The following operations will be obtained for each case where only output abnormality occurs.

(1)
When only an oscillation abnormality occurs, that is, when an abnormality occurs only in the oscillator 1 of the working system X, the operation shown in FIG. The switching time to the system Y is determined by the delay time D1 set in the delay timer 9.

  At this time, since an input abnormality is also generated, step S2 in FIG. 2A is executed, and as a result, the delay time D2 of the delay timer 12 is kept at the same time D2.

  Therefore, when the time D1 elapses within the period until the time D2 elapses, the input abnormality is eliminated, so that the timer signal d is not generated from the delay timer 12, and the output switching unit 10 is not switched.

  In addition, since Konoki also causes an output abnormality, step S4 in FIG. 2B is also executed. As a result, the delay time D3 of the delay timer 15 is kept at the time D3 as it is.

  Therefore, also in this case, when the time D1 elapses within the period until the time D3 elapses, the output abnormality disappears, so that the timer signal f is not generated from the delay timer 15. Of course, the output switching unit 13 is not switched.

  Therefore, as described above, the operation shown in FIG. 4 is performed as in the case of the prior art, and the switching time from the active system X to the standby system Y is determined by the delay time D1 set in the delay timer 9. There is no.

(2)
When only an input abnormality occurs, that is, when an abnormality occurs only in the OFDM modulator 3 of the working system X, step S1 in FIG. 2A is executed, so the delay time of the delay timer 12 is changed to D1. As a result, the input switching unit 10 is switched from the working system X to the standby system Y after the time D1 has elapsed.

  At this time, an output abnormality is also generated. In this case, step S4 in FIG. 2B is executed. As a result, the delay time D3 of the delay timer 15 is kept at the same time D3, and when the time D1 elapses during the period until the time D3 elapses, the output abnormality disappears. The timer signal f is not generated from the delay timer 15, and the output switching unit 13 is not switched.

  On the other hand, since no oscillation abnormality has occurred at this time, the oscillation switching unit 7 does not operate. Therefore, the switching time from the active system X to the standby system Y in this case is set in the delay timer 10. Determined by the delay time D1.

(3)
When only an output abnormality occurs, that is, when an abnormality occurs only in the transmitter 5 of the active system X, step S3 in FIG. 2 (b) is executed, so the delay time of the delay timer 15 is changed to time D1. As a result, the output switching unit 13 is switched from the active system X to the standby system Y after the time D1 has elapsed.

  At this time, since neither an input abnormality nor an oscillation abnormality is further generated, the oscillation switching unit 7 and the input switching unit 10 do not operate. As a result, the delay time of the delay timer 15 is not increased. There is no possibility that a problem will occur due to the change to the time D1, and therefore the switching time from the active system X to the standby system Y in this case is determined by the delay time D1 set in the delay timer 15.

  Therefore, according to this embodiment, even if an abnormality occurs in any stage of the transmission system, the switching time from the active system X to the standby system Y becomes the same time D1, so the abnormality switching time is shortened, Stop time can be minimized.

It is a block block diagram which shows one Embodiment of the dual-system automatic switching apparatus by this invention. It is a flowchart for demonstrating operation | movement of one Embodiment of this invention. It is a block block diagram which shows the prior art of a dual-system automatic switching apparatus. It is a timing diagram for demonstrating the switching operation by the prior art of a dual type automatic switching apparatus. It is a timing diagram for demonstrating the switching operation by the prior art of a dual type automatic switching apparatus. It is a timing diagram for demonstrating the switching operation by the prior art of a dual type automatic switching apparatus.

Explanation of symbols

1,2: Oscillator (current system X, standby system Y)
3, 4: OFDM modulator (working system X, standby system Y)
5, 6: Transmitter (working system X, standby system Y)
7: Oscillation switching unit 8: Oscillation abnormality detection unit 9: Delay timer (D1)
10: Input switching unit 11: Input abnormality detection unit 12: Delay timer (D2)
13: Output switching unit 14: Output abnormality detection unit 15: Delay timer (D3)
16: Control unit (CPU)
a: Oscillation abnormality detection signal b: Timer signal (for oscillation switching)
c: Input abnormality detection signal d: Timer signal (for input switching)
e: Output abnormality detection signal f: Timer signal (for output switching)
REF: OFDM modulator reference signal

Claims (1)

Two oscillation units, an oscillation switching unit for switching these oscillation units to a working system and a standby system, two modulation units to which a signal is supplied from the oscillation unit selected by the oscillation switching unit, and these modulation units An input switching unit that switches between the active system and the standby system, two transmission units to which signals are supplied from the modulation unit selected by the input switching unit, and output switching that switches these transmission units to the active system and the standby system An oscillation abnormality detection unit that detects an abnormality from the output of the oscillation switching unit and generates an oscillation abnormality detection signal, and an input abnormality that detects an abnormality from the output of the input switching unit and generates an input abnormality detection signal A detection unit; an output abnormality detection unit that detects an abnormality from the output of the output switching unit and generates an output abnormality detection signal; and a first that supplies the oscillation abnormality detection signal to the oscillation switching unit with a delay of time D1 The delay unit and the input abnormality detection signal are timed D2 ( D2> D1) a second delay unit that delays and supplies the output switching unit to the input switching unit, and a third delay unit that delays the output abnormality detection signal by time D3 (D3> D2) and supplies the output abnormality detection signal to the output switching unit. With
The oscillation switching unit is switched between an active system and a standby system by an oscillation abnormality detection signal generated from the oscillation abnormality detection unit,
The input switching unit is switched between the active system and the standby system by an input abnormality detection signal generated from the input abnormality detection unit,
In the dual system automatic switching device of the transmission device, the output switching unit is configured to be able to switch between the active system and the standby system by the output abnormality detection signal generated from the output abnormality detection unit,
Provide a control unit for inputting the oscillation abnormality detection signal, the input abnormality detection signal and the output abnormality detection signal,
When only the input abnormality detection signal is input, the time D2 set in the second delay unit is changed to the time D1, and when only the output abnormality detection signal is input, the third delay unit A dual system automatic switching device characterized in that an operation for changing the time D3 set to time D1 to the time D1 is executed by the control unit.

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