JP2012174002A - Transmission device and transmission method - Google Patents

Abstract

A transmission apparatus and a transmission method capable of suppressing the risk of unstable operation as much as possible at least for a high-priority apparatus even if a voltage drop occurs in supplied power. provide.
A transmission / reception unit 101 transmits / receives a plurality of signals with priorities set via one transmission cable, and receives supply of power. The cable loss calculation unit 113 calculates cable loss. The margin calculation unit 113 calculates the margin of power from the maximum supply power of the supplied power, the cable loss, and the power consumption of a plurality of devices that respectively process a plurality of signals. The control unit 113 performs control so as to supply power supply in order from an apparatus that processes a signal having a high priority according to the power margin.
[Selection] Figure 1

Description

  The present invention relates to a transmission apparatus and a transmission method in which a plurality of signals are transmitted and received via a single cable, and power is supplied from a partner apparatus that transmits and receives the signal via the single cable.

  In general, monitoring is performed by transmitting an analog video signal obtained by imaging a subject with a camera via a coaxial cable and displaying the analog video signal on a monitor or recording it on a recording device. As one of such monitoring systems, a monitoring system that supplies power to the camera from the monitor or recording device side via a coaxial cable that transmits an analog video signal to the camera in order to reduce wiring effort and cost. There is.

  Recently, surveillance cameras that transmit and receive analog video signals and digital signals via a single coaxial cable have also appeared.

  As a technique combining the above, an analog video signal and a digital signal are transmitted / received via one coaxial cable, and power is supplied from one device transmitting / receiving to the other device via this single coaxial cable. Has been proposed (see, for example, Patent Document 1).

JP 2006-352216 A

  However, in the technique of Patent Document 1, power can be supplied from one device that transmits and receives to the other device through this single coaxial cable, but the resistance of the coaxial cable and the power supply are supplied. No mention is made of how to deal with a voltage drop in the power supply due to an increase in power consumption of each device. The resistance value of the coaxial cable varies depending on the type of the coaxial cable and the length of the installed coaxial cable, that is, the cable length. The resistance value of the coaxial cable also changes depending on the ambient temperature and aging. In addition, the power consumption of each device to which power is supplied varies depending on the usage situation. Therefore, if the resistance value of the coaxial cable is large or the power consumption of each device is large, the power supply voltage becomes less than the standard of each device to which the power supply is supplied, and the operation of these devices becomes unstable. There is a fear.

  Thus, the problem to be solved by the present invention is that even if a voltage drop occurs in the supplied power, the operation is unstable for at least a high priority device among the devices to which the power is supplied. It is an object of the present invention to provide a transmission apparatus and a transmission method that can suppress the risk of becoming as much as possible.

In order to solve the above problems, the present invention provides the following apparatus and method.
1) A first apparatus (20) located outside the predetermined area (1) and a transmission apparatus (10) located inside the predetermined area (1) for transmitting and receiving signals via one transmission cable (30) A transmission / reception unit (101) that transmits and receives a plurality of signals with priorities set in advance and receives supply of power from the first device (20) via one transmission cable (30); A plurality of signal input / output units (106, 107) for inputting / outputting the above-mentioned signals to / from the plurality of second devices (40, 50) located inside the predetermined area (1), which respectively process the plurality of signals. ), A cable loss calculation unit (111) that calculates a cable loss that is a power loss in one transmission cable (30), a maximum supply power that can be supplied by the first device (20), a cable loss, Multiple second From the power consumption of the devices (40, 50), the margin calculation unit (111) for calculating the margin of power, and the power supplied by the transmission / reception unit (101) are converted into the second device (40, 50). 50) A power supply unit (113, 114) that converts each power source power into each of the plurality of second devices (40, 50) and a margin calculation unit (111). When the calculated power margin exceeds a predetermined value, the power supply unit (113, 114) is controlled to supply power to all of the plurality of second devices (40, 50). When the power is less than or equal to the predetermined value, the power supply power in order from the second device (50) that processes a signal having a higher priority among the plurality of second devices (40, 50) according to the power margin. The power supply unit (113, 114) is controlled to supply Transmission device, characterized in that it comprises control unit (111) to.
2) The transmission device according to 1), wherein the transmission / reception unit (101) transmits / receives a plurality of signals including at least a digital signal and an analog video signal.
3) The cable loss calculation unit (111) repeatedly calculates the cable loss, and the margin calculation unit (111) calculates the power margin every time the cable loss calculation unit (111) calculates the cable loss. 1. The transmission device according to 1).
4) A first apparatus (20) located outside the predetermined area (1) and a transmission apparatus (10) located inside the predetermined area (1) for transmitting and receiving signals via one transmission cable (30) Transmission / reception step for transmitting and receiving a plurality of signals with priorities set in advance via one transmission cable (30) and receiving supply of power from the first device (20) (Step S501) and a plurality of signal input / output steps for inputting / outputting a plurality of signals to / from a plurality of second devices (40, 50) located inside a predetermined area, which respectively process the plurality of signals. (Step S502), a cable loss calculation step (Step S503) for calculating a cable loss which is a power loss in one transmission cable (30), and the first device (20) can be supplied. Margin calculation step (steps S504, S506, S508) for calculating a margin of power from the maximum supply power, cable loss, and power consumption of the plurality of second devices (40, 50), and transmission / reception step The power source power supplied in (Step S501) is converted into the power source power of each of the second devices (40, 50), and each converted power source power is supplied to the plurality of second devices (40, 50), respectively. When the power margin calculated in the power supply step (steps S509, S510) and the margin calculation step (steps S504, S506, S508) exceeds a predetermined value, a plurality of second devices ( 40, 50) is controlled so as to supply power to all of the power sources. When the power is below a predetermined value, a plurality of second devices (40, 50) are selected according to the power margin. Transmission method among, for in order from a second device that processes high priority signal (50), characterized in that it comprises a control step of controlling so as to supply source power (step S509, S510) of.

  According to the transmission apparatus of the present invention, the margin of power supply power to be supplied is calculated, and the power supply power is supplied in order from a device that processes a signal having a high priority among a plurality of devices according to the power margin. As a result, even if a voltage drop occurs in the supplied power supply, among the devices supplied with the power supply, there is a risk that the operation becomes unstable for at least a high-priority device. A transmission apparatus and a transmission method that can be suppressed as much as possible can be provided.

It is a block block diagram of the subunit | mobile_unit adapter which is one Embodiment of the transmission apparatus of this invention. It is a block block diagram of the main | base station adapter connected with a subunit | mobile_unit adapter. It is a system configuration diagram showing an embodiment of a transmission system including a slave unit adapter and a master unit adapter. It is a flowchart which shows one Example of the calculation process of the resistance value of a coaxial cable. It is a flowchart which shows one Example of the power supply process in a subunit | mobile_unit adapter.

[Configuration of slave adapter and master adapter]
Hereinafter, a slave unit adapter which is an embodiment of the transmission apparatus of the present invention and a master unit adapter connected to the slave unit adapter will be described with reference to the accompanying drawings. The slave adapter and the master adapter transmit and receive analog video signals and digital signals via a single coaxial cable. At the same time, the power supply power of the handset adapter itself and power supplies for a plurality of devices connected to the handset adapter are supplied from the base unit adapter to the handset adapter via the single coaxial cable.

  FIG. 1 is a block diagram of a slave adapter according to an embodiment of the present invention. In FIG. 1, the coaxial cable connection unit 101 includes a BNC (Bayonet Neill Concelman) connector for connecting a coaxial cable exposed to the outside of the slave adapter 10, a surge countermeasure component, and the like. As will be described later, an analog video signal and a digital signal are transmitted to and received from the parent device adapter via the coaxial cable connected to the coaxial cable connection unit 101, and power is supplied from the parent device adapter to the child device adapter. .

  A BPF (Band-pass filter) unit 102 has a frequency characteristic that allows a signal of a desired frequency band to pass through. It is assumed that the BPF unit 102 in this embodiment passes a signal in a frequency band of 12 MHz to 44 MHz. The BPF unit 102 bi-directionally transmits a band-passed digital signal between the coaxial cable connection unit 101 and the modem unit 103.

  The modem 103 demodulates the QAM (Quadrature Amplitude Modulation) modulated (quadrature amplitude modulation) digital signal sent from the BPF 102 and sends it to the digital bridge unit 104, and The modulated digital signal is QAM modulated and sent to the BPF unit 102.

  The digital bridge unit 104 mutually converts different digital signal access methods and data transfer protocols on the coaxial cable side and the LAN (Local Area Network) cable side.

  The physical interface unit 105 mutually converts physical layers of digital signals that are different between the coaxial cable side and the LAN cable side.

  The LAN connection unit 106 has a connector for connecting a LAN cable exposed to the outside of the handset adapter 10. The LAN connection unit 106 transmits and receives digital signals between the LAN cable connected to the connector and the physical interface unit 105.

  The analog video input unit 107 has a BNC connector for inputting an analog video signal exposed to the outside of the handset adapter 10 and a filter. The analog video input unit 107 sends the input analog video signal to the video amplification unit 108 through a filter.

  The video amplification unit 108 amplifies the analog video signal sent from the analog video input unit 107, shapes the waveform, and sends the waveform to an LPF (Low-pass filter) unit 109.

  An LPF (Low-pass filter) unit 109 has a frequency characteristic that allows a signal in a desired frequency band to pass through in a low band. The LPF unit 109 in the present embodiment is assumed to pass signals in a frequency band of 30 Hz to 6 MHz. The LPF unit 109 passes the analog video signal amplified and waveform-shaped by the video amplification unit 108 through a low frequency band and sends the analog video signal to the coaxial cable connection unit 101.

  It is assumed that the BPF unit 102 and the LPF unit 109 have impedance characteristics of 75 ohms in the pass band and high impedance characteristics outside the pass band.

  The impedance converter 110 passes the power source sent from the coaxial cable connector 101 and sends it to the power source controller 111. The impedance converter 110 is assumed to have a frequency characteristic that is low impedance in DC (direct current) and high impedance in other cases. The reason for performing impedance conversion is to prevent adverse effects on the characteristics of the filters of the BPF unit 102 and the LPF unit 109 connected in parallel.

  The power supply control unit 111 supplies the power supply power sent from the impedance conversion unit 110 as the power supply power of each block in the slave adapter 10, and also supplies the power supply power to the digital power supply unit 113 and the analog power supply unit 114. .

  The memory 112 stores various data necessary for the control of the power control unit 111 and the like.

  The digital power supply unit 113 and the analog power supply unit 114 have a DC / DC converter circuit, a fuse, and a power output terminal for supplying power to an external device exposed to the outside of the slave unit adapter 10. . The digital power supply unit 113 supplies the power supply power supplied from the power supply control unit 111 as the power supply power of an external digital device by changing the voltage with a DC / DC converter circuit. Here, the digital device refers to a device that is connected to the LAN connection unit 106 and processes a digital signal. The digital power supply unit 113 supplies power supply power having a voltage of minus 48V, for example. The analog power supply unit 114 supplies the power supply power supplied from the power supply control unit 111 as the power supply power of an external analog device by changing the voltage with a DC / DC converter circuit. Here, the analog device refers to a device that is connected to the analog video input unit 107 and processes an analog video signal. The analog power supply unit 114 supplies power supply power having a voltage of 12V, for example. In order to prevent erroneous connection, it is also preferable to use power output terminals having different physical shapes in the digital power supply unit 113 and the analog power supply unit 114.

  Further, the power supply power of the digital device may be supplied by a LAN cable that transmits and receives digital signals using PoE (Power Over Ethernet (registered trademark)) technology that supplies power by a LAN cable. In that case, the power supply power of the digital device is supplied from the LAN connection unit 106.

  If PoE technology is used to supply power for digital equipment, digital signals can be transmitted and received and power can be supplied simply by connecting the digital equipment and the LAN connection unit 106 with a LAN cable. It becomes. Therefore, the connection of the cable is further simplified, and there is an effect that the wiring work for supplying the power supply becomes unnecessary.

  The setting unit 115 performs setting for calculating the resistance value of the cable.

  FIG. 2 is a block diagram of the parent device adapter 20 connected to the child device adapter 10. In FIG. 2, the LAN connection unit 206 has a connector for connecting a LAN cable exposed to the outside of the master adapter 20. The LAN connection unit 206 transmits and receives digital signals between the LAN cable connected to the connector and the physical interface unit 205.

  The physical interface unit 205 mutually converts physical layers of digital signals that are different between the LAN cable side and the coaxial cable side.

  The digital bridge unit 204 mutually converts different digital signal access methods and data transfer protocols between the LAN cable side and the coaxial cable side.

  The modem unit 203 QAM modulates the unmodulated digital signal sent from the digital bridge unit 204 and sends it to the BPF unit 202, and demodulates the QAM modulated digital signal sent from the BPF unit 202 to demodulate the digital bridge unit. 204.

  Similar to the BPF unit 102, the BPF unit 202 passes signals in the frequency band of 12 MHz to 44 MHz. The BPF unit 202 bi-directionally transmits the band-passed digital signal between the modem unit 203 and the coaxial cable connection unit 201.

  The coaxial cable connection portion 201 has a BNC connector for connecting a coaxial cable exposed to the outside of the master adapter 20 and a surge countermeasure component. The coaxial cable connection unit 201 bi-directionally transmits digital signals between the BPF unit 202 and the coaxial cable.

  As with the LPF unit 109, the LPF unit 209 passes signals in a frequency band of 30 Hz to 6 MHz. The LPF unit 209 passes the analog video signal sent from the coaxial cable connection unit 201 through the low frequency band and sends it to the video amplification unit 208.

  The video amplification unit 208 amplifies the analog video signal sent from the LPF unit 209, shapes the waveform, and sends the waveform to the analog video output unit 207.

  The analog video output unit 207 has a BNC connector for outputting an analog video signal exposed to the outside of the parent device adapter 20 and a filter. The analog video output unit 207 outputs the analog video signal sent from the video amplification unit 208 to the outside through the filter from the BNC connector.

  The power supply unit 212 is exposed to the outside of the main unit adapter 20 and connected to an AC (alternating current) power supply, and a switch power supply that converts AC to DC and generates DC power with less ripple noise by a noise filter. A DC power source power is generated from the AC power source power coming from the power source input terminal and supplied to the DC / DC converter 211.

  The DC / DC conversion unit 211 converts the voltage of the DC power generated by the power supply unit 212 and supplies the converted voltage to the impedance conversion unit 210.

  Similar to the impedance conversion unit 110, the impedance conversion unit 210 has a frequency characteristic that is low impedance in DC and high impedance in other cases. The impedance converter 210 supplies the DC power supplied from the DC / DC converter 211 to the coaxial cable connector 201.

  FIG. 3 is a system configuration diagram showing an embodiment of a transmission system configured to include a slave adapter and a master adapter. In FIG. 3, for example, 1 is a store, 2 is an office, and the handset adapter 10 of the store 1 and the base unit adapter 20 of the office 2 are connected by a coaxial cable 30.

  In the store 1, the monitoring camera 40 is installed to monitor the inside of the store 1. The video output terminal of the monitoring camera 40 is connected to the analog video input unit 107 of the slave adapter 10 via a coaxial cable. The monitoring camera 40 is an analog device that is connected to the analog input / output unit 107 and processes an analog video signal, and power is supplied from the analog power supply unit 114 of the slave adapter 10.

  The LAN terminal of the wireless LAN access point 50 is connected to the LAN connection unit 106 of the slave adapter 10 via a LAN cable. The wireless LAN access point 50 is a digital device that is connected to the LAN connection unit 106 and processes a digital signal, and the power is supplied from the digital power supply unit 113 of the slave adapter 10.

  A PC (Personal Computer) 60 (60a, 60b, 60c) is installed in the store 1 to provide a user with an Internet connection service. The PC 60 is connected to the wireless LAN access point 50 through a wireless LAN standard such as IEEE (Institute of Electrical and Electronic Engineers) 802.11n. The wireless LAN access point 50 may be a wired router that connects the PC 60 with a LAN cable.

  In the office 2, the monitor 80 is installed so that the inside of the store 1 can be monitored from the office 2. The video input terminal of the monitor 80 is connected to the analog video output unit 207 of the parent device adapter 20 via a coaxial cable.

  The LAN side terminal of the router 70 is connected to the LAN connection unit 206 of the master adapter 20 via a LAN cable. Further, a WAN (Wide Area Network) side terminal of the router 70 is connected to a network 90 such as the Internet. The master adapter 20 is connected to an AC power source.

  A method for supplying power and a method for transmitting / receiving an analog video signal and a digital signal in a transmission system including such a slave adapter and a master adapter will be described below.

The power supply method includes a power supply method from the master adapter 20 to the slave adapter 10, a method for calculating the resistance value of the coaxial cable 30, and a power supply from the slave adapter 10 to the digital device or analog device. I will divide it into methods.
[Supply power supply method from master adapter 20 to slave adapter 10]
First, a method for supplying power from the parent device adapter 20 to the child device adapter 10 in this embodiment will be described. The power supply unit 212 of the base adapter 20 generates DC power from the incoming AC power and supplies the DC power to the DC / DC converter 211. The DC / DC conversion unit 211 generates power supply power used in each block in the base unit adapter 20, or generates power source power for the handset adapter to be used on the handset adapter 10 side. The power supply for the slave adapter is supplied to the coaxial cable connection unit 201 via the impedance conversion unit 210. The power for the slave unit adapter supplied to the coaxial cable connection unit 201 is supplied to the slave unit adapter 10 via the coaxial cable 30.

The power for the slave unit adapter supplied from the master unit adapter 20 to the slave unit adapter 10 via the coaxial cable 30 is sent to the coaxial cable connection portion 101 of the slave unit adapter 10. The power supply for the slave adapter sent to the coaxial cable connection unit 101 is sent to the power supply control unit 111 via the impedance conversion unit 110.
[First calculation method of resistance value of coaxial cable 30]
The slave adapter 10 supplied with the power for the slave adapter calculates the resistance value of the coaxial cable 30 before supplying the power to the digital device or the analog device. As a first method of calculating the resistance value of the coaxial cable 30, an example of calculating using the type and cable length of the coaxial cable 30 set by the setting unit 115 of the slave adapter 10 will be described.

  The setting unit 115 is composed of, for example, two rotary dip switches. The first rotary dip switch is for setting the type of the coaxial cable 30. In general, coaxial cables of 5C-2V and 3C-2V are widely used in Japan, and cables such as RG59 and URM-70 are widely used overseas. Therefore, for example, the position of the first rotary dip switch is determined as shown in Table 1.

第２のロータリーディップスイッチはケーブル長を設定するもので、たとえば表２のように定める。

The second rotary dip switch sets the cable length and is determined as shown in Table 2, for example.

各種のケーブルの単位長さあたりの抵抗値は既知であるので、これをメモリ１１２に表３のように記憶させておく。

Since resistance values per unit length of various cables are known, they are stored in the memory 112 as shown in Table 3.

以上表１〜３の関係により、第１のロータリーディップスイッチと第２のロータリーディップスイッチとの設定されたポジションから同軸ケーブル３０の抵抗値が算出できる。

As described above, the resistance value of the coaxial cable 30 can be calculated from the set positions of the first rotary dip switch and the second rotary dip switch according to the relationships in Tables 1 to 3 above.

  For example, if the type of the coaxial cable 30 is 5C-2V, the position of the first rotary dip switch is set to 1 from Table 1. If the cable length is 520 m, the position closest to Table 2 is position 5, so the position of the second rotary dip switch is set to 5.

The resistance of the coaxial cable 30 is determined from the resistance value per unit length read from the memory 112 based on the set position of the first rotary dip switch and the cable length based on the set position of the second rotary dip switch. Calculate the value. In this embodiment, the resistance value per unit length of 5C-2V is 0.035Ω / m, and the cable length is 500m, so the cable resistance value is 500 × 0.035 = 17.5 (Ω).
Is calculated.
[Second calculation method of resistance value of coaxial cable 30]
As a second method for calculating the resistance value of the coaxial cable 30, an example in which a test resistor is provided in the slave adapter 10 and the resistance value of the coaxial cable 30 is calculated will be described with reference to the flowchart of FIG. The subject of the operation in the flowchart of FIG. 4 is the power supply control unit 111 unless otherwise specified.

  A mode setting switch is provided as the setting unit 115 of the slave adapter 10. Power supply power is supplied from the parent device adapter 20 to the child device adapter 10 via the coaxial cable 30. In the cordless handset adapter 10, the power supply power supplied from the coaxial cable 30 is supplied to the power supply control unit 111 through the coaxial cable connection unit 101 and the impedance conversion unit 110, and the power supply control unit 111 is activated. When activated, the power supply control unit 111 first checks the state of the mode setting switch of the setting unit 115. When the power supply control unit 111 confirms that the mode setting switch is set to the cable measurement mode, the power supply control unit 111 performs the following processing.

  First, the current I1 at this time is measured in a state where the power supply is supplied only to the power supply control unit 111 (step S401). Next, the power supply control unit 111 switches circuits to insert a test resistor in series in addition to the power supply control unit 111 (step S402), and measures the current I2 at that time (step S403). The resistance value of the test resistor is Rt. Assuming that the power consumption of the power supply control unit 111 in the cable measurement mode is the known Ws, the following equation holds.

Vm = Rca x I1 + Ws / I1 (1)
Vm = Rca x I2 + Rt x I2 + Ws / I2 (2)
Where Vm is the output voltage of the power supply for the slave adapter of the master adapter 20, and Rca is the resistance value of the coaxial cable 30.
(1) and (2)
Rca × I1 + Ws / I1 = Rca × I2 + Rt × I2 + Ws / I2
Rca × (I1-I2) = Ws × (1 / I2-1 / I1) + I2 × Rt
Rca = (Ws × (1 / I2-1 / I1) + I2 × Rt) / (I1-I2) (3)
It becomes. Since the power consumption Ws and the resistance value Rt of the test resistor in the cable measurement mode of the handset adapter 10 are known values, they are stored in the memory 112 in advance.

  The power supply control unit 111 reads from the memory 112 the power consumption Ws in the cable measurement mode of the slave adapter 10 and the resistance value Rt of the test resistor. Then, the resistance value Rca of the coaxial cable 30 is calculated from the resistance value Rt and the measured current values I1 and I2 using the equation (3) (step S404).

  The resistance value of the coaxial cable 30 can be calculated using the first method and the second method described above.

In addition, without setting the mode setting switch in the handset adapter 10, the resistance value of the coaxial cable 30 is calculated by shifting to the cable measurement mode without fail when the power is turned on, or by shifting to the cable measurement mode every predetermined time. You may comprise.
[Supply power supply method from cordless handset adapter 10 to digital and analog devices]
A method for supplying power from the slave adapter 10 to the digital device or analog device using the calculated resistance value of the coaxial cable 30 will be described with reference to the flowchart of FIG. FIG. 5 is a flowchart showing an embodiment of power supply in the handset adapter 10. The subject of the operation in the flowchart of FIG. 5 is the power supply control unit 111 unless otherwise specified.

The base unit adapter 20 converts the power source power generated by the power source unit 212 by the DC / DC conversion unit 211 and outputs the power source power from the coaxial cable connection unit 201 to the coaxial cable 30 as power source power for the slave unit adapter. The coaxial cable connector 101 of the slave adapter 10 is supplied with power for the slave adapter from the master adapter, and transmits and receives digital signals and analog video signals as will be described later (step S501). Digital signals transmitted / received by the coaxial cable connection unit 101 are transmitted / received to / from the wireless LAN access point 50 through the LAN connection unit 106 as will be described later.
The analog video signal transmitted through the coaxial cable connection unit 101 is captured by the monitoring camera 40 and input from the analog video input unit 107 (step S502).

  The power supply control unit 111 calculates the resistance value Rca of the coaxial cable 30 using the first method or the second method described above, and the coaxial cable 30 is calculated from the calculated resistance value of the coaxial cable 30 as follows. The power loss at is calculated (step S503).

If the cable loss is Pca and the power supply for the slave adapter output from the DC / DC converter 211 of the master adapter 20 is Pm, Pca is
Pca = (Pm / Vm) ^ 2 × Rca
Pca = Pm ^ 2 × Rca / Vm ^ 2 (4)
It becomes. Vm is a value determined by the specifications of the DC / DC conversion unit 211 of the parent device adapter 20. Similarly, Pca can be calculated as the maximum cable loss by using the value of the maximum supply power determined by the specification of the DC / DC converter 211 as Pm.

  Therefore, the memory 112 stores in advance the output voltage of the parent device adapter 20 as Vm and the maximum supply power that can be output from the DC / DC converter 211 of the parent device adapter 20 as Pm. The power supply control unit 111 reads the output voltage Vm of the parent device adapter 20 and the power Pm output from the DC / DC conversion unit 211 of the parent device adapter 20 from the memory 112. Then, the cable loss Pca is calculated from Pm and the cable resistance value Rca calculated by the expression (3) using the expression (4).

Next, the power supply control unit 111 determines that the maximum supply power Pm is
Pm ≤ Pca + Pint (5)
Pca + Pint <Pm ≤ Pca + Pint + Pdigi (6)
Pca + Pint + Pdigi <Pm ≤ Pca + Pint + Pdigi + Pana (7)
Pca + Pint + Pdigi + Pana <Pm (8)
The power supply power of each block in the handset adapter 10, the power supply power of the digital power supply unit 113, and the power supply power of the analog power supply unit 114 can be determined.

  However, the maximum power consumption of each block in the handset adapter 10 is Pint, the maximum power consumption of the digital device connected to the digital power supply unit 113 is Pdigi, and the maximum power consumption of the analog device connected to the analog power supply unit 114 is Pana. .

  In the handset adapter 10 of the present embodiment, digital signal transmission / reception is the main purpose, and the power supply priority is higher in the digital power supply unit 113 than in the analog power supply unit 114.

  Pint is calculated by measuring the power consumption of the handset adapter 10 in various states in advance, or is determined as a design specification and stored in the memory 112. The maximum power consumption Pdigi of the digital device and the maximum power consumption Pana of the analog device are determined as specifications of the maximum supply output of the digital power supply unit 113 and the analog power supply unit 114, and are also stored in the memory 112. The power control unit 111 reads Pint, Pdigi, and Pana from the memory 112, and further uses the Pca calculated in step S503, so that the total maximum power consumption is (5), (6), (7), (8) Determine which of the formulas is applicable.

  Specifically, the power supply control unit 111 first determines whether or not equation (5) is satisfied (step S504). If equation (5) holds, the maximum supply power of the power supply control unit 111 is equal to or less than the sum of the cable loss and the power supply power of each block in the handset adapter 10, so that the operation of the handset adapter 10 is stopped or There is a risk of becoming stable. Therefore, a warning message is displayed on a display unit (not shown), and the operation is stopped (step S505).

  If equation (5) does not hold, it is next determined whether or not equation (6) holds (step S506). When the equation (6) holds, the maximum supply power of the power supply control unit 111 is larger than the sum of the cable loss and the power supply power of each block in the slave unit adapter 10. It is less than the sum of the power supply power of the block and the maximum power consumption of the digital device. Therefore, the handset adapter 10 can transmit and receive digital signals and analog video signals, but has no room for supplying power from the digital power supply unit 113 or the analog power supply unit 114 to the outside. Therefore, power is supplied to each block in the slave unit adapter 10 of the modem unit 103, the digital bridge unit 104, the physical interface unit 105, and the video amplification unit 108 to cause the slave unit adapter 10 to function. However, supply of power to the analog power supply unit 114 and the digital power supply unit 113 is not performed. As a result, handset adapter 10 starts transmission / reception of digital signals and transmission / reception of analog video signals, but does not supply power for digital devices or power for analog devices (step S507).

  If equation (6) does not hold, it is next determined whether or not equation (7) holds (step S508). When equation (7) is satisfied, the maximum supply power of the power supply control unit 111 is larger than the sum of the cable loss, the power supply power of each block in the slave adapter 10 and the maximum power consumption of the digital device. And the sum of the power supply power of each block in the handset adapter 10, the maximum power consumption of the digital device, and the maximum power consumption of the analog device. Therefore, handset adapter 10 performs transmission / reception of digital signals and transmission / reception of analog video signals, and there is room to supply power from digital power supply unit 113 to the digital device, but power supply power from analog power supply unit 114 to the analog device. There is no room to supply. Therefore, power is supplied to each block in the handset adapter 10 and the digital power supply unit 113, but power supply power is not supplied to the analog power supply unit 114. Thereby, the handset adapter 10 starts transmission / reception of digital signals and transmission / reception of analog video signals and supplies power to the wireless LAN access point 50 as power for digital equipment, but does not supply power for analog equipment. (Step S509).

  (5) If none of the formulas in (6) and (7) holds, formula (8) will hold, so that the maximum supply power of the power supply control unit 111 is the cable loss and each of the adapters in the slave adapter 10. It is larger than the sum of the power supply power of the block, the maximum power consumption of the digital device, and the maximum power consumption of the analog device. Therefore, the handset adapter 10 transmits and receives digital signals and analog video signals, and has a margin for supplying power from the digital power supply unit 113 and the analog power supply unit 114 to the digital device and the analog device. Therefore, power is supplied to each block in the handset adapter 10, the digital power supply unit 113, and the analog power supply unit 114. As a result, handset adapter 10 starts transmission / reception of digital signals and transmission / reception of analog video signals, and also supplies power from digital power supply unit 113 to wireless LAN access point 50 as power for the digital equipment. Is supplied from the analog power supply unit 114 to the monitoring camera 40 (step S510).

  As described above, the power supply power can be supplied from the parent device adapter 20 to the child device adapter 10, and the power supply power can be supplied from the child device adapter 10 to the digital device or the analog device. This eliminates the need for wiring for supplying power to digital equipment and analog equipment installed in the store.

  In such a power supply procedure, it is also preferable to repeat the calculation of the margin not only at the start of power supply but also periodically thereafter. In that case, Pint is the actual power consumption of each block in the slave adapter 10, Pdigi is the actual power consumption of the digital device connected to the digital power supply unit 113, and Pana is the actual power consumption of the analog device connected to the analog power supply unit 114. If the margin of the power source power is calculated as the power consumption, the margin of the power source power can be calculated more accurately. Further, the actual power consumption Pdigi of the digital device connected to the digital power supply unit 113 is measured and replaced by the actual power consumption of the digital power supply unit 113, and the actual power consumption of the analog device connected to the analog power supply unit 114 is replaced with this. The power consumption Pana may be replaced by measuring the actual power consumption of the analog power supply unit 114.

  Note that it is preferable to notify the power supply state of power supply by displaying it on a display unit (not shown) of the handset adapter 10 because the power supply power can be immediately obtained even when the digital device or analog device cannot be supplied. . When the power supply cannot be supplied, an external power supply is prepared separately from the handset adapter 10 to supply the power supply for digital equipment and analog equipment.

  The power supply control unit 111 also supplies the power supply voltage supplied to the digital device by the digital power supply unit 113 and the power supply supplied to the analog device by the analog power supply unit 114 at the start of supply in steps S507, S509, and S510. It is also preferable to monitor whether the power voltage is appropriate.

  In that case, the power supply control unit 111 monitors the power supply voltage supplied from the digital power supply unit 113 to the digital device and the power supply voltage supplied from the analog power supply unit 114 to the analog device so as to satisfy each desired value. Is compared with a predetermined threshold value. When the voltage is higher than the threshold value, power supply power is supplied to the digital device or analog device. When the voltage is lower than the threshold value, supply of power supply power to the digital device or analog device is stopped.

  Such voltage monitoring is preferably performed not only at the start of power supply in step S507, step S509, and step S510, but also periodically thereafter. However, in the case of monitoring the voltage repeatedly, if the power supply is stopped immediately when the threshold value is exceeded, there is a possibility that an adverse effect may occur. For this reason, it is also preferable to display a warning message or sound a warning buzzer to encourage a response.

  Note that PoE standardized by IEEE 802.3af prescribes power classes as shown in Table 4 according to the performance of the power receiving device. In addition, the power supply device is determined to perform power classification corresponding to which power class the power receiving device corresponds to. Therefore, when the power supply of the digital device is supplied by PoE conforming to the IEEE 802.3af standard, the aforementioned Pdigi is initially set to the default of 15.4 W. After classifying the power receiving devices, the maximum supply power on the power supply side determined for the power class is used as Pdigi. In this way, settings can be made more appropriately. Further, in the IEEE 802.3af standard, minus 44V is defined as the minimum output voltage. Therefore, the power supply control unit 111 may use the specified minus 44 V as a threshold value when the voltage of the power supply power output from the digital power supply unit 113 is monitored.

また、ディジタル電源部１１３やアナログ電源部１１４から電源電力の供給を開始した瞬間に、子機側アダプタ１０内の各ブロックに供給する電源電力の電圧が降下する恐れがある。特に、ディジタル機器やアナログ機器の消費電力が想定外に大きかった場合、消費電力の影響を受け、子機アダプタ１０内の各ブロックに供給する電源電力の電圧が大きく降下して、子機アダプタ１０が動作不能に陥る恐れがある。

In addition, at the moment when the supply of power from the digital power supply unit 113 or the analog power supply unit 114 is started, there is a possibility that the voltage of the power supply supplied to each block in the slave unit side adapter 10 may drop. In particular, when the power consumption of a digital device or an analog device is unexpectedly large, the power supply voltage supplied to each block in the slave unit adapter 10 is greatly reduced due to the influence of the power consumption. May become inoperable.

  In view of this, it is preferable to avoid the inoperable state if the power supply to the digital power supply unit 113 and the analog power supply unit 114 can be stopped by a user instruction by using a dip switch (not shown).

  Thus, the transmission apparatus of the present invention calculates the margin of the power supply power to be supplied, and when the power margin exceeds a predetermined value, the power supply power is supplied to all of the plurality of apparatuses, When the power margin is equal to or less than the predetermined value, the power supply power is supplied in order from the device that processes the signal with the highest priority among the plurality of devices according to the power margin. Even if a voltage drop occurs in the power supply power that is supplied, it is possible to suppress the risk of the operation becoming unstable as much as possible for at least high-priority devices among the devices to which the power supply is supplied. A transmission apparatus can be provided.

[Analog video signal transmission and reception method]
Following the description of the power supply method of the present embodiment, a method for transmitting and receiving analog video signals will be described. The analog video signal captured by the monitoring camera 40 in the store 1 is sent to the analog video input unit 107 of the slave adapter 10. The analog video signal sent to the analog video input unit 107 is amplified and waveform-shaped by the video amplification unit 108 and then sent to the LPF unit 109. Since the LPF unit 109 passes signals in the frequency band of 30 Hz to 6 MHz, the analog video signal passes through the LPF unit 109 and is sent from the coaxial cable connection unit 101 to the coaxial cable 30. As described above, since power is supplied from the master adapter 20 to the slave adapter 10 via the coaxial cable 30, one coaxial cable is connected between the slave adapter 10 and the master adapter 20. The power supply is supplied and the analog video signal is transmitted / received.

  Here, there is a method in which an analog video signal is FM-modulated and transmitted in a frequency band higher than a QAM modulated wave used for transmission of a digital signal, which will be described later. However, it is generally known that the high frequency characteristics of the coaxial cable become worse as the cable length becomes longer. Therefore, the handset adapter 10 of this embodiment is assumed to transmit an analog video signal without modulation.

  The analog video signal transmitted via the coaxial cable 30 is received by the coaxial cable connection unit 201 of the master adapter 20, passes through the LPF unit 209, and is sent to the video amplification unit 208. The analog video signal sent from the LPF unit 209 is amplified by the video amplification unit 208 and subjected to waveform shaping, and then output from the analog video output unit 207 to the outside. The analog video signal output from the analog video output unit 207 is sent to the monitor 80. Thereby, the image in the store imaged with the monitoring camera 40 provided in the store 1 can be browsed on the monitor 80 of the office 2, and the store can be monitored in the office.

In this embodiment, an example in which an analog video signal is transmitted from the slave unit adapter 10 to the master unit adapter 20 is shown, but an analog video signal may be transmitted from the master unit adapter 20 to the slave unit adapter 10.
[Digital signal transmission and reception method]
Following the description of the power supply method of this embodiment and the analog video signal transmission / reception method, the digital signal transmission / reception method will be described. The modulation / demodulation unit 203 of the base adapter 20 and the modulation / demodulation unit 103 of the slave adapter 10 are configured to perform transmission / reception by performing QAM modulation and demodulation on the digital signal.

  At startup, the modem unit 203 of the base adapter 20 first performs quadrature phase amplitude modulation using a 256QAM modulation method and transmits a test signal to try to establish a link. The test signal transmitted from the modem unit 203 is sent to the BPF unit 202. Since the BPF unit 202 passes signals in the frequency band of 12 MHz to 44 MHz, the QAM-modulated test signal passes through the BPF unit 202 and is transmitted from the coaxial cable connection unit 201.

  The test signal transmitted from the coaxial cable connection unit 201 is received by the coaxial cable connection unit 101 of the slave adapter 10 through the coaxial cable 30, passes through the BPF unit 102, and is demodulated by the modem unit 103. When the modem 103 performs demodulation and confirms the test signal, it generates a response signal, performs QAM modulation, and sends the response signal to the BPF 102. The response signal sent from the modem unit 103 passes through the BPF unit 102 and is transmitted from the coaxial cable connection unit 101.

  The response signal transmitted from the coaxial cable connection unit 101 is received by the coaxial cable connection unit 201 of the master adapter 20 via the coaxial cable 30, passes through the BPF unit 202, and is demodulated by the modem unit 203. When the modem unit 203 demodulates and confirms the response signal, the modem unit 203 determines that the link has been established, and thereafter performs communication using the 256QAM modulation method.

  However, if a correct response signal cannot be confirmed within a predetermined time with respect to the transmitted 256QAM test signal, the modem unit 203 changes the modulation method to 64QAM, lowers the modulation rate, and transmits the test signal again.

  In this way, the modem unit 203 and the modem unit 103 transmit test signals using 256QAM, 64QAM, and 16QAM and the modulation schemes that are sequentially reduced in modulation rate while attempting to establish a link, thereby determining the modulation scheme. . Such link confirmation is performed in a predetermined cycle, and the modulation method is confirmed and changed each time.

  The link confirmation method may be configured such that the modem 103 transmits / receives a test signal at a constant cycle as described above, or uses a periodic packet transmitted by the digital bridge unit 104 described later. May be.

  As a result, when the C / N ratio is good, it is possible to perform high-speed transmission / reception with a modulation scheme of 256QAM. If the C / N ratio is poor because the coaxial cable is long or there is a lot of noise due to disturbance, it is possible to reliably transmit and receive by reducing the modulation rate by setting the modulation method to 64QAM, 16QAM, or the like.

  In addition, when the modem 103 of the slave adapter 10 confirms whether or not a link is established with the master adapter 20, it notifies the power controller 111 of the result as a link signal. When the power supply control unit 111 of the slave adapter 10 confirms that the link cannot be established by the link signal sent from the modem unit 103, the power supply control unit 111 stops the supply of the power supply to the digital power supply unit 113. Thereby, when a link cannot be established, useless power consumption can be reduced. If the stop of the supply of power to the digital power supply unit 113 is canceled at the time of confirming the next link after a predetermined cycle, it can be automatically restored when the transmission / reception abnormality is resolved. It is also preferable to display a fixed modulation method on a display unit (not shown), display a warning message when a link cannot be established, or sound a warning buzzer to prompt a response.

  Following the modulation / demodulation unit 103, the operation of the digital bridge unit 104 will be described. The digital bridge unit 104 mutually converts the transfer protocol used on the coaxial cable side and the transfer protocol used on the LAN cable side. Specifically, it is assumed that transmission is performed using a HomePNA (Phoneline Networking Alliance) standard that employs a CSMA / CA (Carrier Sense Multiple Access with Collision Avoidance) half-duplex transmission method on a coaxial cable, for example. On the other hand, on the LAN cable, transmission is performed using Ethernet (registered trademark) that employs a full duplex transmission scheme of CSMA / CD (Carrier Sense Multiple Access with Collision Detection) as a transfer protocol. The digital bridge unit 104 converts these transfer protocols to each other, suppresses collision avoidance during packet transmission, and performs digital signal buffer control for data standby during half-duplex transmission.

  The digital bridge unit 104 of the slave adapter 10 periodically transmits a link confirmation packet to the master adapter 20 connected through the coaxial cable 30 to determine whether a link has been established. When receiving the link confirmation packet, the digital bridge unit 204 of the base adapter 20 transmits a response packet in response thereto. The digital bridge unit 104 of the handset adapter 10 can confirm that the link has been established by confirming the response packet. Similar to the modem unit 103, the digital bridge unit 104 checks such a link in a predetermined cycle. Further, the supply power supply stop / return and the display on the display unit by the link signal are the same as those of the modem unit 103.

  As another method for link confirmation, the modem 103 may transmit and receive a predetermined frequency in the passband of the BPF unit 102 to and from the modem 203 of the base adapter 20 to check the connection. Further, both packets may be exchanged by sending a link confirmation packet from the modem unit 203 of the base adapter 20, and the modem unit 103 of the slave adapter 10 responding thereto.

  When the digital bridge unit 104 of the slave unit adapter 10 and the digital bridge unit 204 of the master unit adapter 20 confirm the link, digital signals are transmitted and received through the coaxial cable 30 between the master unit adapter 20 and the slave unit adapter 10 thereafter. Is done.

  As described above, slave adapter 10 has already transmitted and received analog video signals via a single coaxial cable, and has been supplied with power from master adapter 20 using this single coaxial cable. Therefore, handset adapter 10 transmits and receives analog video signals and digital signals via a single coaxial cable, and power supply power is supplied from base adapter 20 using this single coaxial cable. It becomes.

  Thus, for example, when a browser is activated on the PC 60 installed in the store 10 and a homepage browsing request is made, a digital signal is transmitted / received to / from the LAN connection unit 106 of the slave adapter 10 through the wireless LAN access point 50.

  The digital signal sent to the LAN connection unit 106 of the slave unit adapter 10 is transmitted to the coaxial cable connection unit 201 of the base unit adapter 20 through the coaxial cable connection unit 101. The digital signal sent to the coaxial cable connection unit 201 of the master adapter 20 is output from the LAN connection unit 206, and a connection request is transmitted to the Web server on the Internet 90 through the router 70.

  Then, when a digital signal of the corresponding home page is returned from the Web server, it is returned to the PC 60 through a route reverse to the browsing request, and the home page is displayed on the browser screen of the PC 60. That is, it is possible to provide an Internet connection service in which a user browses a home page with the PC 60 in the store 10.

  For example, an analog video surveillance system is already installed between a store and an office, a surveillance camera is installed in the store, a monitor is installed in the office, and a coaxial cable is installed between the store and the office. It is assumed that If you want to send and receive new digital signals between a store and an office using such an analog video surveillance system, you can lay a new cable or prepare a power supply for digital equipment by applying the present invention. There is no need to do. Therefore, no wiring work is required and cost and labor are not required.

  The cordless handset adapter of this embodiment calculates the margin of the supplied power supply, and supplies the power supply power in the order of the power supply power of the digital device and the power supply power of the analog device according to the margin. Therefore, even if the resistance value of the coaxial cable is large or the power consumption of each device is large and there is not enough power supply power, the risk of the operation becoming unstable with respect to a high priority device can be suppressed. it can.

1 Store 2 Office 10 Slave adapter 20 Master adapter 30 Coaxial cable 40 Monitoring camera 50 Wireless LAN access point 60 (60a, 60b, 60c) PC
70 router 80 monitor 90 network

Claims (4)

In the first apparatus located outside the predetermined area and the transmission apparatus located inside the predetermined area for transmitting and receiving signals via one transmission cable,
A transmission / reception unit that transmits and receives a plurality of signals with priorities set in advance via the one transmission cable, and receives supply of power from the first device;
A plurality of signal input / output units for inputting / outputting the plurality of signals to / from a plurality of second devices located inside the predetermined area, which respectively process the plurality of signals;
A cable loss calculation unit for calculating a cable loss that is a power loss in the one transmission cable;
A margin calculation unit that calculates a margin of power from the maximum supply power that can be supplied by the first device, the cable loss, and the power consumption of the plurality of second devices;
A power supply unit that converts the power supply supplied by the transmission / reception unit to the power supply power of each of the second devices, and supplies each of the converted power supplies to the plurality of second devices,
When the power margin calculated by the margin calculation unit exceeds a predetermined value, the power supply unit is controlled to supply power to all of the plurality of second devices, When the power is less than or equal to a predetermined value, according to the power margin, the power supply is configured to supply power in order from a second device that processes a signal having a higher priority among the plurality of second devices. And a control unit that controls the supply unit.   The transmission apparatus according to claim 1, wherein the transmission / reception unit transmits / receives a plurality of signals including at least a digital signal and an analog video signal. The cable loss calculation unit repeatedly calculates the cable loss,
The transmission apparatus according to claim 1, wherein the margin calculating unit calculates a power margin each time the cable loss calculating unit calculates a cable loss. A transmission method used for a first apparatus located outside a predetermined area and a transmission apparatus located inside the predetermined area for transmitting and receiving signals via one transmission cable,
A transmission / reception step of transmitting and receiving a plurality of signals with priorities set in advance via the one transmission cable and receiving supply of power from the first device;
A plurality of signal input / output steps for inputting / outputting the plurality of signals to / from a plurality of second devices located inside the predetermined region, respectively processing the plurality of signals;
A cable loss calculating step of calculating a cable loss that is a power loss in the one transmission cable;
A margin calculating step of calculating a margin of power from the maximum supply power that can be supplied by the first device, the cable loss, and the power consumption of the plurality of second devices;
A power supply step for converting the power supply supplied in the transmission / reception step into power supply power for each of the second devices, and for supplying each of the converted power supplies to the plurality of second devices;
When the power margin calculated in the margin calculation step exceeds a predetermined value, control is performed to supply power to all of the plurality of second devices, while the power margin is less than the predetermined value. A control step of controlling to supply power in order from a second device that processes a signal having a higher priority among the plurality of second devices according to the power margin. A transmission method characterized by the above.

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