KR100227757B1 - An option structure of car-audio using the resistance - Google Patents

Abstract

The present invention relates to an option structure of a car audio using a resistor, comprising a first array resistor having the same resistance value to form a predetermined data according to whether the array connection is connected in series with a first array resistor for inducing voltage distribution from an input power source. At the same time, it consists of a second array resistor and a third array and a fourth array resistor that vary the resistance of each array resistor, thereby setting the regional classification of the car audio, that is, the classification by country or the base of the clock or the secret code. Caraudio's optional features are selected using resistors only, which reduces production costs and improves manufacturing efficiency.

Description

Car Audio Option Structure

The present invention relates to an option structure of car audio using a resistor, and in particular, it is a low-cost resistor that excludes an expensive diode matrix structure that sets a regional classification of a car audio, that is, a country classification or clock setting or secret code. By using only, the option structure of the car audio is selected, and relates to the option structure of the car audio using the resistance that leads to the reduction of production cost.

In general, car audio allows the user to select optional functions that are used in each country in order to select smooth functions according to exports. This function selection uses the diode as shown in Figure 1, to select the option mode, which will be described in more detail as follows.

First of all, the component includes three audio signals, KS0, KS1, and KS2, which output ring counting signals using the microcomputer 70 of the car audio and the signal output port of the microcomputer 70, respectively. A plurality of diodes (D) used to apply and block the signals output from the kisken terminals (KS0, KS1, KS2) to the signal input terminal of the microcomputer 70, and predetermined data set through the diode (D). In accordance with the key input terminals Kin0, Kin1, Kin2, Kin3 provided on the signal input side of the microcomputer 70 and specific data applied from the key input terminals Kin0, Kin1, Kin2, Kin3 When a control signal of the microcomputer 70 is outputted, whether or not a secret code is set in a predetermined option function, i.e., the base of the clock used for car audio or car audio, is set by this control signal. It consists of data outputting signal status It is.

In addition, the ring counting signal of the key scan terminals KS0, KS1, KS2 is shown in FIG. 2, which outputs a high signal of a predetermined period from the key stent terminal KS0, and then outputs a high signal at the key scan terminal KS1. The key scan terminal KS2 successively outputs a high signal and the key scan terminal KSO outputs a high signal to perform a continuous ring counter.

The following describes the operation of the above-described configuration according to such a ring counting.

First, in order to select a predetermined option function, a plurality of diodes, for example, two diodes are contacted to the anode side on the key scan terminal KS0 axis, and the cathode side is connected to the key input terminal Kin1 and the key input terminal Kin3, respectively. As it is connected, the high signal output of the key scan terminal KSO described above is a high signal input to the key input terminal Kin1 and the key input terminal Kin3.

As shown in the drawing, the high signal of the key scan terminal KS1 causes the high signal to be applied to the key input terminal Kin0, the key input terminal Kin1, and the key input terminal Kin3, and then the key scan terminal KS2. The high signal is applied to the key input terminal Kin1 and the key input terminal Kin2 so as to apply a high signal.

That is, the above-described key input terminals Kin0, Kin1, Kin2, and Kin3 obtain binary data of '0101' from the first clock pulse, receive '1101' data from the second clock pulse, and then return '0110' data. It is to obtain a predetermined function according to the data.

This allows the microcomputer 70 to output a corresponding command from the input binary data so as to select a regional classification, that is, a country-specific code, or a binary or hexadecimal display of a clock mounted on a car audio. Either select or set the car audio to embed a secret code.

Therefore, depending on the contact point of the diode, the optional function of the currently produced car audio is selected.

However, the option selection structure of such a configuration not only increases the production cost from expensive diodes as a plurality of diodes corresponding to data for selecting an option is used, but also allows one kiken terminal and four key input terminals. The number of data decoding is limited to 16, which causes a problem that there is no solution when the number of options is increased.

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and eliminates expensive diodes, connects a plurality of resistors of a predetermined value, and selects option data according to a voltage value distributed from an input voltage. The resistance element not only improves production cost and improves work efficiency, but also provides an optional structure of car audio using a resistor that allows a wide range of data selection by using a large number of resistance values.

In order to achieve the above object, the present invention provides a first array resistor configured with the same resistance value to induce voltage distribution from an input power supply, and predetermined data depending on whether the array resistors are connected in series. And a second array resistor and a third array and a fourth array resistor having different resistance values of the array resistor.

1 is a diagram illustrating a diode matrix structure for selecting an optional function of a conventional car audio.

FIG. 2 is a diagram illustrating a data scan pulse signal according to FIG. 1.

3 is a diagram illustrating a structure for selecting an option function of a car audio to which the present invention is applied.

<Explanation of symbols for main parts of drawing>

1: microcomputer AR1: first array resistance

AR2: second array resistor AR3: third array resistor

AR4: fourth array resistor A-D: signal input terminal of microcomputer

R2: discrete resistor of the second array resistor R3: discrete resistor of the third array resistor

R4: individual resistor of the fourth array resistor

Thus, the present invention will be described in detail with reference to the illustrated drawings.

First, FIG. 3 is a diagram illustrating an option structure of a car audio according to the present invention, wherein a first array resistor (ARRAY RESISTANCE: AR1) and a first array resistor are connected to the input power source Vdd in parallel to achieve voltage distribution. The second array resistor AR2, which is connected in series with AR1 and is determined in accordance with the input data, and has a specific resistance value, is connected in series with the second array resistor AR2, and the second array resistor ( A third array resistor AR3 having a different resistance from AR2, a fourth array resistor AR4 connected in series with the third array resistor AR3 and having a different resistance from the third array resistor AR3; The microcomputer 1 is connected between the array resistors AR2 to AR4 and the first array resistor AR1 to receive a voltage distributed therefrom and select predetermined data according to the input voltage.

The microcomputer 1 has four input terminals A, B, C, and D and a plurality of output terminals.

The following describes the operation of the present invention made of such a configuration.

First, according to the embodiment of the present invention, the first array resistor AR1 is set to 68KΩ, the second array resistor AR2 is set to 47KΩ, and the third array resistor AR3 and the fourth array resistor AR4 are 15K and 8.1KHz respectively.

The array resistors AR2 to AR4 vary the number of resistors according to input data. For example, the second array resistor AR2 has one resistor of 47 KΩ connected to the B input terminal of the microcomputer 1. The third array resistor AR3 is set to 15KΩ each of the A, B, and D input terminals of the microcomputer 1, and the fourth array resistor AR4 has one resistor of 8.1KΩ as the D terminal of the microcomputer 1. Assume that it is connected.

Then, a certain voltage is applied to each input terminal of the microcomputer 1, and the microcomputer 1 can select the corresponding code by digitizing and decoding the signal.

If this is described in more detail by specifying in the following table.

Here, the power supply Vdd is set to an arbitrary voltage, and only the input voltage of the microcomputer shown in Table 1 is a ratio with respect to the power supply Vdd.

R2 R3 R4 Rin Rtotal Vin / Vdd 0 0 0 0KΩ 68KΩ 0 0 0 One 8.1KΩ 76.1KΩ 0.1064 0 One 0 15KΩ 83KΩ 0.1807 0 One One 23.1KΩ 91.1KΩ 0.2535 One 0 0 47KΩ 115KΩ 0.4086 One 0 One 55.1KΩ 123.1KΩ 0.4476 One One 0 62KΩ 130KΩ 0.4769 One One One 70.1KΩ 138.1KΩ 0.5076

As described above, the voltage Vin flowing into the input terminal of the microcomputer 1 includes a second array resistor connected in series to one of three input resistors, that is, one of a plurality of resistors included in the first array resistor AR1. The resistance R2 corresponding to AR2 and the combined resistance values according to the presence or absence of the resistors R3 and R4 corresponding to the third and fourth array resistors AR3 and AR4 are set.

In addition, the resistance value Rin shown in Table 1 is a composite value of the resistors R2, R3, and R4, and the resistance value Rtotal is a composite resistance including up to the resistance value of the first array resistor AR1, and 68 KΩ is added up. will be. In addition, the above-described voltage Vin is a distribution voltage input to the microcomputer 1 and is a result value inferred from the following equation.

Vin = (Rin / R _total ) * Vdd

Therefore, the voltage applied to the input terminals A, B, C, and D of the microcomputer 1 varies its numerical value according to the resistance to be connected, so that an optional function is selected using this.

In other words, in the embodiment as shown in FIG. 3, only 68Kdd of the first array resistor AR1 and 15KΩ of the third array resistor AR3 are connected in series to the A input terminal of the microcomputer 1 so that the voltage Vdd is distributed. This is applied at a voltage ratio of 0.1807 as shown in Table 1.

In addition, the B input terminal of the microcomputer 1 is 0.4769, which is a voltage distribution ratio of 62KΩ (47KΩ + 15KΩ), which is a combined value of 68KΩ of the first array resistor AR1 and the second and third array resistors AR2, AR3. The C input terminal of the microcomputer 1 is not connected to an array resistor, so a voltage of 0 V is applied. The D input terminal of the microcomputer 1 has a ratio of the combined resistance of 23.1 KΩ and the first array resistance AR1 of 68 KΩ of 15 KΩ and 8.1 KΩ of the third and fourth array resistors AR3 and AR4 connected in series. Phosphorus 0.2535 is applied.

Therefore, the divided voltage ratios applied to the input terminals A, B, C, and D of the microcomputer 1 set 0.1807, 0.4769, 0, and 0.2535. If the power supply Vdd is a rated voltage of 5V, the input terminals A, B, C, and D of the microcomputer 1 are input at 0.90V, 2.38V, 0V, and 1.26V through the above ratio. Digitize it with the microcomputer 1 and decode it.

This is to determine whether the voltage applied to the microcomputer 1 is a voltage value within a previously set range, and sets the voltage within this range to one digitized code. That is, when a plurality of signals and a plurality of voltages are input through the signal input terminals A, B, C, and D of the microcomputer 1, a plurality of digitized codes are formed and decoded so that the car audio can be decoded. The optional function is selected.

In addition, this optional feature allows you to select a country-specific code that represents a regional classification, or to set the base of the watch on your car audio so that it can be displayed in 24- or 12-decimal notation. It is to indicate whether or not.

As described above, the present invention excludes the expensive diodes that set the regional classification of the car audio, that is, the country classification or the clock setting or the secret code, etc., and selects the option of the car audio using only low-cost resistors. By reducing the use of diodes, not only the production cost is reduced, but also the array resistance (ARRAY RESISTANCE) that is already set up, it is possible to assemble as a whole without the need for assembling separately like a diode, thereby improving manufacturing efficiency. It has an effect that improves.

Claims (3)

In the circuit that selects the optional function of the car audio, The microcomputer (1) and the microcomputer (1) for selecting an optional function of car audio by judging whether a plurality of input signals are voltages within a reference value range, classifying the data according to the determined reference value, and outputting the data. A first array resistor AR1 for directly distributing a voltage applied from a power source Vdd by directly connecting the same resistance to each of the plurality of signal input terminals A, B, C, and D provided; A second array resistor AR2 connected in parallel between the resistor AR1 and the plurality of signal input terminals A, B, C, and D, respectively, to distribute a predetermined voltage, and the second array resistor AR2; A third array resistor AR3 connected in series with each resistor R2 included in the second array resistor AR2, and a resistor R3 included in the third array resistor AR3. ) Is connected in series to the second array resistor (AR2) and the third array resistor The fourth array resistor (AR4) to be synthesized with (AR3), and each of the resistors (R4) included in the fourth array resistor (AR4) is a common ground, the option structure of the car audio using a resistor. The method of claim 1, wherein the array resistors AR2-AR4 are configured to set the respective resistors R2, R3, and R4 embedded in the array resistors AR2-AR4 according to an optional function of the microcomputer 1. Optional structure of car audio using the resistance. The method of claim 1, wherein the first array resistor (AR1), the second array resistor (AR2), the third array resistor (AR3) and the fourth array resistor (AR4) are 68KΩ, 47KΩ, 15KΩ and 8.1KΩ, respectively. Car audio option structure using a resistor, characterized in that.

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