KR100470949B1 - Computer musical instrument with light emitting device - Google Patents

Abstract

The present invention relates to an electronic musical instrument used by connecting to a parallel port of a personal computer, and installs a light emitting device for each input key in the 'electronic musical instrument used by connecting to a computer' (Application No. 10-1999-0033652) The present invention relates to an electronic musical instrument with the addition of a light emitting device for emitting a device corresponding to a key to be turned on according to the sheet music data. The light emitting device according to the present invention includes two types of a dynamic driving method using an LED matrix circuit and a static driving method using a latch.

Description

Computer musical instrument with light emitting device

The present invention relates to an electronic musical instrument used by connecting to a parallel port of a personal computer, and installs a light emitting device for each input key in the 'electronic musical instrument used by connecting to a computer' (Application No. 10-1999-0033652) The electronic musical instrument which added the light-emitting device which makes the element corresponding to the key which should be turned ON according to the score data All.

The applicant of the present invention is currently applying for an invention (electronic musical instrument used in connection with a computer) as shown in FIG. 1 (as of January 2002, the registration procedure is in progress). The first application of the invention shown in Figure 1 is to connect the circuit portion having a key input unit 10 for inputting the instrument sound to the parallel port 30 of the computer to the main point to generate the instrument sound in the computer. The electronic musical instrument according to the applicant's prior application has arranged input keys by a key matrix circuit using 12 pins for output and 5 pins for input among the parallel ports of a PC, and when a specific key is pressed, the software (drive program) ), The computer generates a sound signal corresponding to the key. In the prior application, since a separate power source must be used, the user is burdened by the use of a power adapter or a battery, and inconveniences due to the complexity of the wiring.

Accordingly, the present inventors receive power directly from the parallel port used in the prior application, and install a light emitting device in the electronic instrument and a light emitting element in each input key (for example, a keyboard, etc.) to be turned on according to the score data. By automatically turning on the light emitting device assigned to the, the user has completed the present invention by trying to add a function that can be easily played and learned by pressing the lighted input key.

Therefore, the main object of the present invention is to install the light emitting device in the electronic instrument and to light up the light emitting element assigned to the input key to be turned on according to the score data by installing the light emitting element on each input key (for example, keyboard, etc.). For a computer having a light-emitting device To provide electronic musical instruments.

Another object of the present invention is to provide an electronic musical instrument for a computer having a light emitting device, characterized in that power is supplied from a computer through a parallel port without using a separate power supply means.

Power supply from parallel port

The power supply from the computer using the parallel port is driven by one or more of the pins to which the open-collector output buffer is connected among the parallel ports. To maintain the HIGH state at all times.

Specifically, it will be described with reference to FIG. Fig. 2 is a pin configuration diagram of a general parallel port. Since some of the configuration pins are connected to the open collector output buffer (see Fig. 3), a "1 (HIGH)" signal is always output to this open collector terminal by a drive program. In this case, the HIGH state becomes 5V, which makes it possible to use the power supply Vcc. 2 and 3 shows that pins usable as Vcc are pins 1, 14 and 17. In addition, the ground GND may be used from Nos. 19 to 25 already assigned as ground.

Addition of light emitting device

The light emitting method of the light emitting device in the present invention is a dynamic driving method and a switch Static driving method is possible.

<Dynamic driving method>

A circuit of the dynamic drive type light emitting device is shown in FIG. In Fig. 1, a 4-bit signal is input from a circuit part 20 of an electronic instrument to a binary decimal decoder (202, hereinafter referred to as a "BCD converter"), and an 8-bit signal is input to a multiplexer MUX 206. Able to know. On the output lines of the BCD converter 202 and the multiplexer 206, a switch array 204 is arranged in a matrix. The switch array 204 constitutes a key matrix scan circuit known in the art.

4, in the dynamic drive type light emitting device, a line branched from a 4-bit line input to the BCD converter 202 of FIG. 1 is input to the first BCD converter 401a, and 8 bits input to the multiplexer 206. FIG. A 7-bit line of the lines branched from the line is input to the second BCD converter 401b, and the remaining 1-bit line is input to the enable / disable terminal E. FIG. That is, the key matrix circuit and the light emitting device are driven together by the BCD converter 202 and the multiplexer 206.

The output bit of the second converter 401b is inverted and output as opposed to the output bit of the first converter 401a. As shown in FIG. 4, each output bit forms a matrix circuit in which LEDs are connected to the intersections thereof.

The circuit operation of FIG. 4 will be described. When E is an enable signal, the first converter 401a outputs "0" only to the binary output pin corresponding to the input BCD. It will output "1", and if E is a disable signal, it will output "1" on all output pins. In contrast, when E is an enable signal, the second converter 401b outputs “1” only at the binary output pin corresponding to the input BCD and “0” at the remaining output pins. If E is the disable signal, all output pins output "0". In this way, the LED connected to each matrix contact emits light when "0" is output on the vertical line and "1" is output on the horizontal line.

In the LED matrix circuit of Fig. 4, since each LED is assigned to each input key of the key input section, driving the LED and scanning the key switch occur at the same time. Therefore, in the circuit of FIG. 4, when "0" or "1" is output to the E line of the parallel port by the drive program, it is possible to control that the selected LED is turned on or off. Therefore, when the score data is loaded from the drive program and the LED at the position specified in the score data is lit, the LED is assigned to each key switch (input key), so the user sees the input key with the LED turned on and presses the input key. So you can play while pressing.

<Static Driving Method>

Static driving method is shown in FIG. The static driving method represents an embodiment in which the LED is driven by using a latch element. In a digital logic circuit, a latch is a device for storing one or more bits. The latch is a device for temporarily holding or storing a state of a signal and holding a specified position or condition until it is returned to its previous state by external means. it means.

Similarly to FIG. 4, 10 bits out of 12 bits in which a line diverged from the 4-bit input line input to the BCD converter 202 of FIG. 1 and an 8-bit branch diverged from the 8-bit input line input to the multiplexer 206 are combined. Is input to the BCD converter 501, and the remaining two bits are connected to the enable terminal "E" of the BCD converter 501 and the data input terminal "D" of the latches 503a, b, c, ..., respectively. . In the circuit of Fig. 5, the anode end of the LED is connected to the output Q of each latch 503a, b, c, ..., respectively. Vcc is applied to the cathode of the LED.

The operation of the static driving circuit constructed as shown in FIG. 5 will be described. When E is enabled, only G _n corresponding to the 10-bit address input to the BCD converter 501 among the input Gs of the latches 503a, b, c, ... becomes HIGH, and when E is disabled, G _n All of these become LOW. When G becomes HIGH, D is outputted as Q. When G becomes LOW, Q maintains the previous Q value regardless of the D value. In the circuit of Fig. 5, the LED is turned on by Vcc when Q to which the anode of the LED is connected becomes LOW. If the signal on the E line changes to disable after being lit, the lit state is maintained as it is.

Therefore, when the score data is loaded from the drive program and the LED at the position specified in the score data is lit, the LED is assigned to each key switch (input key), so the user sees the input key with the LED turned on and presses the input key. So you can play while pressing.

According to the invention, 1) the computer is now popular, the key without the need for a separate sound source It is possible to implement electronic musical instruments at a low price because only an arrangement is required. 2) New functions can be continuously added by upgrading the driving program. 3) It is possible to store electronic musical instruments separately because it is easily separated from the computer. 4) In addition to the advantages of the previous application that it is easy to carry when using a portable computer such as a notebook,

Since the power can be supplied from the parallel port, there is no need to provide a separate power supply device, and according to the display of the light emitting element assigned to the input key, the user can easily play the music and learn the main method easily.

1 is a schematic configuration diagram of a prior application.

Figure 2 is a pin configuration of a general parallel port.

Figure 3 is a block diagram of the pin that can be used as a power line of the parallel port.

4 is a circuit diagram of a dynamic drive type light emitting device.

5 is a circuit diagram of a static drive type light emitting device.

<Description of Drawing>

Binary Decimal Decoder 202, Switch Array 204, Multiplexer 206, First BCD Converter 401a, Second BCD Converter 401b, BCD Converter 501, Latch 503a, b, c, .. .)

Claims (4)

Power (Vcc, GND) is supplied through the parallel port by the drive program installed in the personal computer (PC), and the computer outputs N-bit test value through the output port of the parallel port. The computer includes a BCD converter 202 in which M bit values are input from the N-bit test values output from the computer, and a multiplexer in which (NM-1) bit values are input from the N-bit test values output from the computer. In electronic instruments used in conjunction with A line branched from the M bit line input to the BCD converter 202 is input, and outputs a binary value corresponding to the BCD of the branched M bit data, the first BCD converter 401a; A second BCD converter for inputting a line branched from the (NM-1) bit line input to the multiplexer 206, and inverting and outputting a binary value corresponding to the BCD of the branched (NM-1) bit data. 401b), An enable wire E output from the parallel port and connected to an enable terminal of the first BCD converter 401a and the second BCD converter 401b; An LED array connected to a contact between each output bit of the first BCD converter 401a and each output bit of the second BCD converter 401b to form a matrix circuit, Wherein each LED is assigned to each key switch and emits a specific LED by a drive program of a PC. Power (Vcc, GND) is supplied through the parallel port by the drive program installed in the personal computer (PC), and the computer outputs N-bit test value through the output port of the parallel port. The computer includes a BCD converter 202 in which M bit values are input from the N-bit test values output from the computer, and a multiplexer in which (NM-2) bit values are input from the N-bit test values output from the computer. In electronic instruments used in conjunction with A line branched from the M bit line input to the BCD converter 202 and a line branched from the (NM-2) bit line input to the multiplexer 206 are input, and these branched M bit data and (NM) are input. -2) a BCD converter 501 for outputting a binary value corresponding to a BCD of bit data, An enable line E output from the parallel port and connected to an enable terminal of the BCD converter 501; Latches 503a, b, c, ... receiving the output bits of the BCD converter 501 as inputs; A plurality of LEDs having one pole connected to the output terminal Q of each latch 503a, b, c, ... And a data input line D output from the parallel port and connected to the data input terminals of the respective latches (503a, b, c, ...). The computer with a light emitting device according to claim 1 or 2, wherein N = 12, M = 4. Electronic musical instrument for computer. The electronic musical instrument for a computer having a light emitting device according to claim 1 or 2, wherein Vcc is at least one of the open collector output pins among the pins of the parallel port.