KR0152047B1 - Power-saving type data-transmission apparatus of satellite broadcasting system - Google Patents

Abstract

The present invention relates to a transmission and reception apparatus of a satellite broadcasting system, and more particularly, to a data transmission and reception apparatus using a smart card of a satellite broadcasting system that periodically operates and detects only a related circuit for detecting data transmitted when a power is turned off. Conventionally, when a signal such as a smart card data request is transmitted through a satellite broadcast when power is off, the satellite signal can be detected only when the satellite receiver is always powered. However, the present invention provides an advantage of preventing unnecessary power consumption by detecting smart card data by periodically operating only an associated circuit for detecting received data without supplying power to the satellite broadcasting receiver.

Description

Power Saving Data Transceiver for Satellite Broadcasting System

1 is a block diagram illustrating a power saving data transmission and reception apparatus of a satellite broadcasting system according to an embodiment of the present invention.

2 is a flow chart for explaining the operation of the microprocessor 15 in the FIG.

* Explanation of symbols for the main parts of the drawings

10: satellite related means 11: channel decoder

13 source decoder 15 microprocessor

17: smart card reader 18: modem transmission unit

19: secondary power supply unit 20: TV-related means

21: Image processor 23: Monitor

25: main power supply

The present invention relates to a transmission and reception apparatus of a satellite broadcasting system. In particular, in order to always detect a signal required by a satellite broadcasting station, even when the power is turned off, power is supplied to the satellite reception related circuits periodically so as to respond to the required signal. The present invention relates to an energy-saving data transmission / reception apparatus of a configured satellite broadcasting system.

In general, a satellite broadcaster is equipped with a smart card. Here, a smart card is a kind of IC card in which a subscriber number, usage history, etc. are recorded. When the satellite broadcasting station requests the data recorded on the smart card by applying the satellite broadcasting signal, the corresponding receiver is configured to decode the signal and send the data recorded on the smart card to the satellite broadcasting station through the modem. Here, the request signal of the data applied from the satellite broadcasting station is included in the digital signal of the satellite broadcasting signal. Therefore, power must be supplied to the TV receiver in order to recognize this signal, and power should always be supplied to at least the satellite broadcasting part even when the TV is OFF. Therefore, in this case, a problem arises in that unnecessary power loss increases.

Accordingly, an object of the present invention is to detect a signal required by a satellite broadcasting station by periodically operating only the satellite reception-related circuitry to detect the smart card data request signal even when the TV off, and to respond to this problem in order to solve this problem. An energy-saving data transmission / reception apparatus of a broadcasting system is provided.

In order to achieve the above object, a feature of the present invention is a satellite broadcasting system comprising: satellite related means for detecting a satellite signal and receiving and processing a smart card data request signal included in the satellite signal, separated from the satellite related means. TV-related means for signal processing to display a video signal, storing a predetermined time value, counting a preset standby time in a standby state in which a minimum TV supply power is applied at power-off, and a coefficient value preset A microprocessor that outputs a power supply control signal to the sub-power unit for a predetermined time when the time value is reached, and supplies power to the satellite related means for a predetermined time each time the power supply control signal of the microprocessor is applied. Supply a sub power supply unit and the standby state and TV dedicated power to the TV related means The present invention relates to a power saving data transmission / reception apparatus of a satellite broadcasting system including a main power source.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating a power saving data transmission and reception apparatus of a satellite broadcasting system according to an embodiment of the present invention. The apparatus of the present invention is largely composed of two parts, satellite related means 10 and TV related means 20.

In order to send a signal requesting data recorded on a smart card, a satellite broadcasting station inserts a predetermined coded signal into a digital broadcasting signal and sends it to the satellite. The satellite broadcasts to each subscriber.

When the TV power is ON, the main power supply 25 supplies power to each component. The channel decoder 11 detects the satellite broadcast signal and demodulates the coded data. In this case, the data refers to various service signals such as a video signal and a smart card data request signal. The source decoder 13 receives a video signal and various data mixed with the video signal from the channel decoder 11 and processes it separately. The image processor 21 receives a video signal separated from the source decoder 13 and processes the signal so that it can be displayed on the screen of the monitor 23. In addition, the microprocessor 15 receives a smart card data request signal for requesting the smart card data transmission among the separate data other than the video signal from the source decoder 13. Then, the microprocessor 15 outputs a control signal for outputting the recorded signal to the modem transmitter 18 to the smart card reader (! 7). The smart card reader 17 outputs data recorded in accordance with this control signal, that is, data such as subscriber number and usage history, to the modem transmitter 18. The modem transmitter 18 transmits the data requested from the satellite broadcasting station through the telephone line.

When the TV power source is OFF, no power is supplied to the satellite related means 10, and the TV related means 20 is in a standby state. In the standby state of the TV, the minimum power is supplied to the microprocessor 15 in order to maintain data of the microprocessor 15 or detect a TV ON signal of the remote controller when the TV is OFF. For example, if a user watches a K channel and then turns off the TV and then turns the TV on again, the K channel being watched before is displayed on the monitor. The microprocessor is always supplied with minimal power to do this. The present invention utilizes this function of the microprocessor 15. The microprocessor 15 checks the preset standby time N. After N hours, the power supply start signal is output to the sub power supply unit 19 for supplying power to the satellite related means 10. The sub power supply unit 19 supplies power to the satellite related means 10. Since the power supply is applied to the satellite related means 10, the smart card reader 17 receives the smart card data output control signal from the microprocessor 15 and transmits the prestored data to the modem transmission unit as in the case of TV ON. 18) The modem transmitter 18 transmits the authorized smart card data to the satellite broadcasting station through the telephone network. The microprocessor 15 checks a predetermined M time when power is supplied to the satellite related means 10. After this time, the microprocessor 15 outputs a power supply end signal to the sub power supply unit 19. The sub power supply unit 19 stops supplying power in accordance with this control signal. The TV related means 20 returns to the standby state again. The microprocessor 33 checks the N time again and outputs a control signal to the sub power supply unit 19 to operate the satellite related means 10, and the sub power supply unit 19 operates time of the satellite related means 10. The power is supplied to the satellite related part 10 by M hours. During this time, if there is no request for data or the request for the same data transmitted previously, the process returns to standby mode again.

2 is a flowchart for explaining the operation of the microprocessor 15 in the FIG. 1 apparatus. The microprocessor 15 first determines whether the TV is powered on or off (step 210). If the power is ON, it is determined whether there is a signal for requesting smart card data (step 250). If there is a smart card data request signal, a control signal for sending data to the smart card reader 17 is output (step 260). However, if there is no smart card data request signal, the process returns to step 210 and repeats the step.

If the power is OFF, the user checks a predetermined N time, which is a standby time (step 220). After N hours, a control signal for applying power to the satellite related means 10 is applied to the sub power supply unit 19. The secondary power supply unit 19 supplies power to the satellite related means 10 (step 230). Next, the microprocessor 15 checks M time for supplying power from the sub power supply unit 19 to the satellite related means 10, and determines whether M time has passed (step 240). If the M period has passed, the process returns to step 210 and repeats the step. However, if M time has not elapsed, it is determined whether there is a smart card data request signal (step 250). If there is a smart card data request signal, a control signal for transmitting the recorded data is output to the smart card reader 17 (step 260). However, if there is no smart card data request signal, the process returns to step 240 and repeats the steps. For example, once again, if the standby time N is 10 hours and the time M to be supplied to the satellite related means 10 is 10 minutes, the satellite broadcasting receiver is 10 minutes every 10 hours. Data applied to the satellite related means 10 can be detected and responded to.

Accordingly, the present invention relates to a digital satellite broadcasting system having bi-directionality in which a TV receiver can receive and retransmit a signal unlike a method in which a conventional TV receiver only receives a general supply signal of a transmitter. In the past, unnecessary power consumption occurred because a signal received only when the satellite receiver was always supplied with power was detected. However, the present invention provides an advantage of avoiding unnecessary power consumption by periodically detecting satellite broadcast data at the same time, without periodically supplying power to the satellite broadcast receiver and only detecting an associated circuit for detecting a smart card data request signal or the like when the power is turned off.

Claims (4)

A satellite broadcasting system comprising: satellite related means for detecting a satellite signal and receiving and processing a smart card data request signal included in the satellite signal; TV related means for signal processing to display a video signal separated from the satellite related means; Stores the preset time value, counts the preset standby time in the standby state where the minimum TV supply power is applied when the power is turned off, and controls the power supply to the secondary power supply unit when the count value reaches the preset time value. A microprocessor for outputting a signal for a predetermined time; A sub power supply unit supplying power to the satellite related means for a predetermined time every time the power supply control signal of the microprocessor is applied; And a main power supply for supplying the standby state and power dedicated to the TV to the TV-related means. 2. The apparatus of claim 1, wherein the satellite related means comprises: a channel decoder for detecting the satellite signal; A source decoder for receiving the smart card data request signal and outputting the smart card data request signal to the microprocessor; A smart card reader for storing the smart card data; And a modem transmitter for transmitting data applied from the smart card reader according to the control signal of the microprocessor. The method of claim 1, wherein the satellite related means detects a request signal of the smart card data during a predetermined time period when power is supplied from the sub-power supply unit, and transmits data through the modem transmission unit if there is a request signal of the smart card data. Energy-saving data transmission and reception device of a satellite broadcasting system. The apparatus of claim 1, wherein the predetermined time value is changeable.