JPH0379727B2 - - Google Patents

Description

[Detailed Description of the Invention] [Summary] The interface section of a handheld device is configured with an optical interface, power is supplied to the optical interface section via a reed switch, and data transfer with the host is performed. The reed switch is turned on by a magnet only when the handheld device is set in the connector.

[Industrial application field]

The present invention is a handheld device that transfers data via an optical interface section with a host computer, and power is supplied to the optical interface section of the handheld device only when the handheld device is set in a connector. This invention relates to interface circuits for handheld devices.

[Conventional technology]

There are two ways to connect a handheld device to a host computer: mechanical connectors and optical interfaces.

[Problem to be solved]

The former has problems with reliability due to the connection and disconnection of connectors, and the latter requires a signal and external light identification circuit in the receiving circuit to prevent malfunctions caused by external light, resulting in increased power consumption.

The present invention was created in view of this point, and it is an object of the present invention to provide a simple, highly reliable, and low power consumption interface circuit for handheld equipment.

[Means for solving problems]

FIG. 1 is a diagram showing the principle of the present invention. As shown in FIG. 1a, the handheld device 1 incorporates a reed switch 10. As shown in FIG. When the handheld device 1 is placed in the recess of the connector 2, the magnetic force of the magnet 12 turns on the lead switch 10. Connector 2 is connected to a host computer via a serial interface line. When the handheld device 1 is set to the connector 2,
The two are optically connected, and signals can be exchanged.

As shown in FIG. 1b, power is supplied from a battery 23 to the main body 1a and the optical interface 1b of the handheld device. However, power is supplied to the optical interface section 1b via the reed switch 10. Therefore, when the reed switch 10 is off, no power is supplied to the optical interface section 1b.

〔Example〕

Fig. 2 is a diagram showing an example of a handheld device and a connector, Fig. 3 is a diagram showing the back side of the handheld device,
FIG. 4 is a diagram showing the configuration of the entire system. In the figure, 1 is a handheld device, 2 is a connector,
3 is a liquid crystal display, 4 is an enter key, 5 is an item key, 6 is a light receiving element, 7 is a light emitting element, 8 is a light emitting element, 9 is a light receiving element, 10 is a reed switch, 11 is a printed board, 12 is a magnet , 13
indicate host computers, respectively.

The handheld device 1 includes a liquid crystal display 3, an enter key 4, an item key 5, a light emitting element 8, a light receiving element 9, a read switch 10, and the like.
The reed switch 10 is mounted on a printed board 11 located inside the handheld device 1. For example, the liquid crystal display 3 initially displays a menu that says ``Your order.'' When the user takes a customer's order and inputs, for example, 1 cup of coffee by operating the key 5, the liquid crystal display 3 displays the menu ``Please place your order.'' It is displayed as 1 piece. After confirming with the customer and pressing the enter key 4, the information of 1 coffee is loaded into the memory of the handheld device 1 to be sent to the host computer, and the above menu is displayed on the LCD display 3. be done. Although not shown, there is a transmission switch in the handheld device 1, and when it is desired to send the transmission information stored in the memory to the host computer, the transmission switch is turned on.

The connector 2 includes a light receiving element 6, a light emitting element 7, a magnet 12, and the like. The connector 2 has a recess for accommodating the handle head device 1, and a magnet 12 is embedded in the bottom of this recess. When the handheld device 1 is set in the recess of the connector 2, the light emitting element 8 and the light receiving element 6 face each other, the light receiving element 9 and the light emitting element 7 face each other, and the reed switch 10 is turned on by the magnetic force of the magnet 12. When the reed switch 10 is turned on, power is supplied to the optical interface section 1b of the handheld device 1, and data can be transferred between the handheld device 1 and the host computer 13. As shown in FIG. 4, a plurality of handheld devices 2 are connected to a host computer 13 via a bus. When the user wants to send data to the host computer 13, he turns on the sending switch and sends the data to the handheld device 1.
Set it to the nearby connector 2.

FIG. 5 is a diagram showing an example of an electric circuit of a handheld device. In the figure, 1a is the main body of the handheld device 1, 1b is the optical interface portion of the handheld device 1, 14 is the processor, and 15 is the main body of the handheld device 1.
RAM, 16 ROM, 17 decoder, 18 key matrix, 19 selector, 20 asynchronous interface adapter, 21 modulator,
22 represents a demodulator, and 23 represents a battery.

The processor 14 is RAM 15 or ROM 16
It executes the program inside. RAM1
5 includes menu information, control tables, auxiliary programs, buffers, work areas, etc.
The ROM 16 stores basic programs. Menu information, auxiliary programs, control information, etc. can be sent from the host computer 13 to the handheld device 1. The key matrix 18 has, for example, 16×16 keys. The decoder 17 decodes 4-bit information and selects one key string. For example, if it is "0000", the leftmost key string will be selected, and if it is "1111", the rightmost key string will be selected. The selector 19 has a function of sequentially sending out 16 pieces of key information outputted from a selected key string onto the bus in groups of four. The asynchronous interface adapter 20 is a communication interface circuit. Portions 3, 14 to 20 constitute a main body portion 1a. The transmitting terminal S of the asynchronous interface adapter 20 is connected to the modulator 21
The receiving terminal R is connected to the demodulator 22. The output of the modulator 21 is input to the light emitting element 8, and the output of the light receiving element 9 is input to the demodulator 22. Portions 8, 9, 21, and 22 constitute an optical interface section 1b. Battery 23
supplies power to the main body portion 1a and the optical interface portion 1b. Optical interface section 1
Power is supplied to the reed switch 10 through the reed switch 10. Therefore, when the reed switch 10 is not turned on, the optical interface section 1b does not operate.

FIG. 6 is a diagram showing an example of the electrical circuit of the connector. In the figure, 24 is a demodulator, 25 is a modulator, 26 and 27 are asynchronous interface adapters, 28 is a RAM, 29 is a ROM, and 30 is a processor. The output of the light receiving element 6 is input to the demodulator 24, and the output of the modulator 25 is input to the light emitting element 7. The output of the demodulator 24 is input to the receiving terminal R of the asynchronous interface adapter 26, and the output from the transmitting terminal S of the asynchronous interface adapter 26 is input to the modulator 25. Symbols 6, 7, 24, 25, 26 are connectors 2
It constitutes the optical interface section of the Asynchronous interface adapter 26, asynchronous interface adapter 27, RAM 28, ROM 29 and processor 30 are connected to the internal bus. The transmitting terminal S and receiving terminal R of the asynchronous interface adapter 27 are connected to the host computer 13 via a serial interface line.

Data transfer between the handheld device 1 and the connector 2 is performed, for example, using a response confirmation method. The data sent from handheld device 1 is temporarily stored in RAM 2.
It is stored in 8. Then, when the host computer 13 makes an inquiry such as "Do you have any data to send?", the data to be sent from the RAM 28 is sent to the host computer 13.

The reason why signals are transmitted and received between the handheld device 1 and the connector 2 by performing modulation and demodulation is to prevent flickering of fluorescence or the like from being mistaken for a signal. For this purpose, a signal with a completely different frequency as a carrier is modulated, and during demodulation, a bandpass filter is used to cut out frequencies other than the signal band.

FIG. 7 is a diagram showing an example of the connection between the demodulator and the asynchronous interface adapter in the handheld device 1. In the figure, 31 indicates a transistor. The base of transistor 31 is connected to reed switch 10 via a pull-up resistor. Further, the output of the demodulator 22 is applied to the base of the transistor 31. The receiver terminal R of the asynchronous interface adapter 20 is connected to the collector of a transistor 31, which is connected to the power supply Vcc via a pull-up resistor. When the reed switch 10 is off, the signal input to the receiving terminal R is at a high level. If you leave the high level as no signal, reed switch 1
When 0 is off, the receiving terminal R of the asynchronous interface adapter 20 is in a no-signal state.

〔Effect of the invention〕

As is clear from the above description, according to the present invention, the reed switch is turned on by the magnet only when the handheld device is set in the connector.
Since power is supplied to the optical interface section, the reed switch is off during normal operation, thus eliminating malfunctions caused by external light and power consumption by the optical interface section. be able to.

[Brief explanation of drawings]

FIG. 1 is a diagram showing the principle of the present invention, FIG. 2 is a diagram showing an example of the handheld device and connector of the present invention, FIG. 3 is a diagram showing the back side of the handheld device of the present invention, and FIG.
The figure shows the overall system configuration, Figure 5 shows an example of the electric circuit of a handheld device, Figure 6 shows an example of the electric circuit of the connector, and Figure 7 shows the demodulator and asynchronous interface. - It is a diagram showing an example of connection of an adapter. 1...handheld device, 2...connector, 3...
...LCD display, 4...Enter key, 5...
...Item key, 6...Light receiving element, 7...Light emitting element,
8... Light emitting element, 9... Light receiving element, 10... Reed switch, 11... Printed board, 12... Magnet, 13... Host computer.

Claims (1)

[Scope of Claims] 1. The interface section of the handheld device 1 for exchanging signals between the handheld device 1 and the connector 2 is an optical interface section 1b, and the power supply to the optical interface section 1b is led.・When the handheld device 1 is set to the connector 2 through the switch 10, the magnet 1 embedded in the connector 2
An interface circuit for a handheld device, characterized in that a reed switch 10 is turned on by the magnetic force of No. 2.