KR100467516B1 - Portable Computer with Infrared Transmit and Receive Signal Direction - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable computer having an infrared transmitting / receiving signal direction changing function. The present invention relates to a portable computer that outputs infrared signal transmission data, receives infrared reception data, and receives a refractive control signal according to whether the infrared reception data is input. An input and output controller; An infrared signal transmitter for generating an infrared transmission signal according to the infrared signal transmission data and outputting the infrared signal to a peripheral device: an infrared signal receiver for receiving an infrared reception signal emitted from the peripheral device and outputting the infrared reception data; And a prism that refracts an infrared transmission signal and a reception signal, a prism driving unit which rotates the prism according to the infrared refraction control signal to change a direction to change an infrared signal transmission direction of an infrared signal transmitter or a signal reception direction of an infrared signal receiver; And a transmission / reception signal direction switching unit having a lens unit provided on the front surface of the prism to diffuse the refracted transmission signal. Thus, the inconvenience of the user manually manipulating the directions and positions of the infrared signal transmitter and receiver is eliminated.

Description

Handheld Computer with Infrared Transceiver Signal Redirection

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable computer having an infrared transmission / reception signal redirection function, and more particularly, to a computer system that wirelessly performs data communication between a computer and its peripherals or computers and various electronic devices using infrared rays. The present invention relates to a portable computer having an infrared transmission / reception signal redirection function capable of automatically orienting an infrared beam between objects.

In general, as well as the exchange of data between the computer and other computers, data transmission and communication between the computer and peripheral devices such as printers, keyboards, and the like have been made by installing wired lines for data transmission between the devices. However, the use of such a device increases the number of peripheral devices used, which complicates the surrounding environment of the computer, and makes it difficult for a user to connect or disconnect them as necessary. In addition, in the case of a portable computer that emphasizes mobility, the use of such a wire line causes more inconvenience. Therefore, in order to solve this problem, a device has been developed that enables communication between a computer and a peripheral device wirelessly using infrared rays including specific data, instead of data communication with a computer and a peripheral device through a wired line.

Hereinafter, an infrared ray transmitting and receiving device for this conventional data communication will be described with reference to the accompanying drawings. 1 is a block diagram of a portable computer having a conventional infrared transmission and reception means, and FIG. 2 is a functional block diagram illustrating an infrared transmission and reception process. As shown in FIG. 1, a portable computer 10 having an infrared signal transmitting and receiving means generally includes a keyboard 12 for inputting data desired by a user, a system circuit part 15 including a system, forming a lower case, It consists of the display part 13 and infrared transmitting / receiving part 11 which mounted display apparatuses, such as LCD. As shown in FIG. 2, the system circuit unit 15 is provided with a central processing unit CPU 20, an input / output controller 21, and an infrared ray transmitting / receiving unit 22 for processing an input signal. In FIG. 2, reference numerals 31 and 32 denote input / output controllers and infrared transmitter / receivers of other peripheral devices 30 communicating with the portable computer 10, respectively.

The operation of the portable computer including the conventional infrared transceiver is as follows. First, when a user issues a predetermined command through the keyboard 12, the command is processed by the CPU 20. When the result processed by the CPU 20 needs to control another peripheral device 30 having an infrared signal receiver, the control signal is input to the input / output controller 21, and the input / output controller 21 is an infrared transmitter / receiver. Control 22 to output the corresponding infrared signal. As shown in FIG. 1, the generated infrared signal is emitted to the infrared reception area A-A 'through the infrared transceiver 11. At this time, when another peripheral device having an infrared signal receiving unit is within the area A-A ', the signal is received through the infrared transmitting and receiving unit 32, and outputs it through the input / output controller 30 to control the peripheral device 31.

However, in the data communication using the conventional infrared ray, the infrared ray transmitting and receiving unit 32 of the peripheral device 30 receiving the data must be within the infrared signal region A-A 'emitted from the portable computer 10 to receive the infrared signal. In order to achieve this orientation, the user must manually manipulate the direction and position of the transmitter and receiver. Therefore, in the above-described prior art, it is inconvenient for the user to manipulate the direction of the infrared signal by hand in precisely aligning the transmitter and the receiver, and it is easy to adjust the direction at a close distance, but at a distance of 1 meter or more, the two sides are aligned. There was a problem that must be taken care of.

Therefore, the technical problem to be achieved by the present invention is to implement a user passive method in which the infrared signal is automatically refracted and the infrared signal direction of the transceiver is adjusted even if the user does not manipulate the directions and positions of the infrared signal transmitter and receiver by hand. To provide a portable computer.

In order to achieve the above object, a portable computer having an infrared transmission / reception signal direction switching function of the present invention includes a display unit and a system circuit unit, and outputs infrared signal transmission data and receives infrared reception data according to a user's command. An input / output controller for outputting a refraction control signal depending on whether the infrared reception data is input; An infrared signal transmitter for generating an infrared transmission signal according to the infrared signal transmission data and outputting the infrared signal to a peripheral device; An infrared signal receiver for receiving an infrared signal received from the peripheral device and outputting the infrared data; and a prism for refracting the infrared transmission signal and the received signal, and rotating the prism according to the infrared refraction control signal to change the direction of the infrared signal And a prism driver for switching an infrared signal transmission direction of the signal transmitter or a signal reception direction of the infrared signal receiver, and a transmission / reception signal direction switching unit including a lens unit provided on the front surface of the prism to diffuse the refracted transmission signal.

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

3 is a block diagram of an infrared transceiver device for data communication of the present invention, Figure 4 is a cross-sectional view of the refractive means of the infrared transceiver device applied to the present invention, Figure 5 is a perspective view of the refractive means of the infrared transceiver device of the present invention. ,

As shown in FIG. 3, an infrared transceiver for data communication according to the present invention includes an input / output controller 50, an infrared signal receiver 51, an infrared signal transmitter 52, a lens unit 55, and a transmission / reception signal direction switching unit ( 53). In addition, the transmission and reception signal direction switching unit 53 includes a prism driving means 60 and a prism 54 including a motor 61 and a motor control unit 62.

The input / output controller 50 generates infrared signal transmission data for driving a peripheral device according to a user's command and outputs the infrared signal transmission data to the infrared signal transmitter 52. The infrared signal transmitter 52 generates an infrared transmission signal according to the infrared signal transmission data and outputs the infrared transmission signal to a peripheral device (not shown) through the transmission / reception signal direction switching unit 53. At this time, when the peripheral device receives the infrared transmission signal, the peripheral device performs the operation according to the infrared transmission signal and feeds the result back to the portable computer having the infrared transmission and reception signal direction switching function of the present invention using the infrared signal. The feedback signal is for informing the portable computer having the infrared transmission / reception signal direction changing function of the present invention that the peripheral device has received the infrared transmission signal. Accordingly, depending on the characteristics of the peripheral device, when receiving the infrared transmission signal, a separate reception signal may be generated and fed back to the portable computer having the infrared transmission / reception signal direction switching function of the present invention.

The feedback signal is received by the infrared signal receiver 51 of the infrared signal transceiver of the present invention, and when such a signal is received, the input / output controller 50 determines that the transmission of the signal is completed. However, when the infrared signal is output in the infrared transceiver device of the present invention but the peripheral device is not located in the region of the output infrared signal, and thus the peripheral device does not receive the infrared transmission signal, the infrared signal receiver 51 receives the feedback signal. I can't. In this case, the input / output controller 51 automatically generates an infrared refraction control signal and outputs it to the transmission / reception signal direction switching unit 53. The transmission and reception signal direction changing unit 53 refracts the infrared transmission signal generated from the infrared signal transmission unit 52 when receiving the infrared refraction control signal. When the peripheral device receives the refracted infrared transmission signal, the feedback signal is output from the peripheral device, and the input / output controller 50 which receives the signal through the infrared signal receiving unit 51 controls the transmission / reception signal direction switching unit 53. So that the infrared transmission signal is no longer refracted. According to another embodiment of the present invention, when the feedback signal is not input continuously while refracting the infrared signal, when the feedback signal is input through the infrared signal receiver 51 from the peripheral device input and output controller 50 is the transmission and reception signal It may be made to generate a signal to stop the operation of the turning section 53. Preferably, a known light emitting diode may be used as the infrared signal transmitting unit 52, and a light receiving diode may be used as the infrared signal receiving unit 51.

The transmission / reception signal direction changing unit 53 includes a prism 54 that refracts the infrared transmission signal and a prism driver 66 that changes the direction of the prism 54 according to the infrared refracting control signal. The prism driver 60 may adopt any device as long as it can change the direction of the prism part according to the refractive control signal. According to a preferred embodiment of the present invention, the prism driving unit 60 drives the motor 61 according to the infrared ray refraction control signal and the motor 61 for rotating the prism 54 to change the refraction direction of the prism. The motor control part 62 is comprised. The motor 61 should be rotated at an appropriately slow speed so that the transmission and reception of the infrared signal can be made stable, and a bidirectional motor may be employed to rotate in both directions according to the signal of the input / output controller 50. More preferably, the lens unit 55 for diffusing the refracted infrared transmission signal may be provided on the front surface of the prism 54.

Infrared transmit signal refraction means according to an embodiment of the invention are shown in FIGS. 4 and 5. As shown in FIG. 4, the infrared signal region A-A 'generated from the light emitting diode 70 is refracted to the region B-B' through the prism 54, and the infrared signal thus refracted causes the lens unit 55 to be moved. Through the C-C 'region. When the peripheral device that receives the infrared signal is not in the infrared region C-C ', the prism 54 is rotated by the prism driver 60 to refract the infrared region. In one embodiment of the present invention, a toothed gear 71 is installed around the prism 54 for the above driving. The toothed gear 71 is driven by a drive gear 72 connected to the motor 61 as shown in FIG. When the prism 54 is rotated by such a device, the refractive region B-B 'of the infrared signal is changed so that the peripheral device can receive the infrared signal. In this embodiment, when a signal for driving the motor 61 is output from the motor control unit 62, the motor 61 rotates the prism 54 by 360 degrees. When the prism 54 is rotated 360 degrees, the infrared signal passing through the prism 54 is also refracted in the entire 360 degree direction, and when the directions of the infrared transmitter and the receiver correspond to each other during the rotation, the motor controller 62 The motor 60 is stopped by the output stop signal.

The apparatus of the present invention can be similarly applied to an infrared receiver. That is, like the transmission, the light receiving diode does not receive the infrared signal correctly if the direction of the infrared signal does not form a proper angle with the light receiving diode as the receiving unit. In this case, the prism 54 and the motor control unit 62 are provided in front of the light receiving diode, and the prism 54 is rotated by the motor control unit 62 to change the incident angle of the infrared signal entering the light receiving diode. To receive. Even in this case, the motor 60 is driven until the infrared signal directions of the transmitter and receiver correspond to each other, and the light receiving diode and the light emitting diode may be properly disposed to refract both the infrared transmission signal and the infrared reception signal by one refraction means.

Figure 6 schematically shows an embodiment to which the infrared transceiver of the present invention is applied, the infrared signal transmitted and received from the infrared transceiver 11 of the portable computer 10 is not directly transmitted to other peripherals, It is configured to be transmitted to the infrared transceiver 11 of the host computer 90 by being transmitted through the repeater 80 mounted on the ceiling and emitted by the other repeater 80.

FIG. 7A illustrates an infrared signal region formed by the rotation of a prism installed in the infrared transceiver, and the shape of the emitted infrared region is rotated based on a predetermined center point as the prism rotates. 7B shows an infrared signal region emitted from the infrared transceiver of the present invention, and the circular shape of the infrared rays emitted through the prism has an elliptical shape due to different magnifications of the horizontal and vertical axes. It shows that the transmission in the shape of. In FIG. 7B, the refraction angle θ is determined by the refraction ratio of the prism, and the angle θ corresponding to the major axis a of the infrared region is preferably about 90 °, and the angle θ corresponding to the minor axis b of the infrared region. Is preferably about 60 degrees.

In the present invention, the peripheral device includes all devices that can be driven wirelessly by an infrared signal, including a printer, a computer, a TV, a monitor, and the like, and the infrared signal transmitting and receiving device for data communication of the present invention is directly controlled by a user. In addition to devices such as portable computers, personal computers, and the like, the device may be installed in the peripheral device to enable infrared transmission and reception regardless of the position and angle of the device and the peripheral device controlled by the user.

Therefore, in the portable computer for transmitting and receiving infrared data, instead of a user active method in which a user directly manipulates a device in order to orient the infrared signal on both sides of a transceiver, the infrared signal is automatically refracted by the infrared signal. By implementing a user passive (passive) method that can match the infrared signal direction, not only is easy to use, but also the transmission and reception of the infrared signal is accurate. In particular, the present invention eliminates the inconvenience that users of low age have to manually operate the system to adjust the direction of the wireless infrared signal.

1 is a portable computer having a conventional infrared transceiver.

2 is a functional block diagram illustrating an infrared transmission and reception process.

3 is a functional block diagram of a portable computer having an infrared transmission and reception signal redirection function of the present invention.

4 is a cross-sectional view of the refraction means of the infrared transceiver device of the present invention.

5 is a perspective view of the refraction means of the infrared transceiver device of the present invention.

6 is an embodiment to which a portable computer having an infrared transmission and reception signal redirection function of the present invention is applied.

Fig. 7A is an infrared signal region formed by the rotation of a prism in a portable computer having an infrared transmitting / receiving signal direction changing function of the present invention.

7B is an infrared signal region emitted from a portable computer having an infrared transmission / reception signal redirection function according to the present invention.

Explanation of symbols on main parts of drawing

10: portable computer 11: infrared transceiver

12: keyboard 20: CPU

21, 31, 50: I / O controller 22, 32: infrared transceiver

30: peripheral 51: infrared signal receiver

52: infrared signal transmitter 54: prism

55: lens 61: motor

62: motor control unit 71: toothed gear

72: drive gear 80: repeater

90: host computer

Claims (3)

A portable computer having a display portion and a system circuit portion, An input / output controller configured to output infrared signal transmission data according to a user's command, receive infrared reception data, and output a refractive control signal according to whether the infrared reception data is input; An infrared signal transmitter for generating an infrared transmission signal according to the infrared signal transmission data and outputting the infrared signal to a peripheral device; An infrared signal receiver for receiving an infrared signal emitted from the peripheral device and outputting the infrared data; And A prism for refraction of an infrared transmission signal and a reception signal, and a prism driving unit for changing an infrared signal transmission direction of an infrared signal transmitter or a signal reception direction of an infrared signal receiver by rotating the prism in accordance with an infrared refraction control signal, A portable computer comprising a transmission / reception signal direction changer provided on a front surface and having a lens unit configured to diffuse a refracted transmission signal. The portable computer of claim 1, wherein the prism driving unit comprises a motor for changing the direction of the prism and a motor control unit for driving the motor according to the infrared refraction control signal. The portable computer of claim 1, wherein the transmission / reception signal redirection unit is positioned at an upper end of the display unit.