KR100547863B1 - Olfactory information transmitter - Google Patents

Abstract

The present invention relates to a device for transmitting olfactory information.

In the olfactory information transmitting apparatus for achieving the present invention, a plurality of filters for separating the physical olfactory signal by each element, and the output of the corresponding filter unit, respectively, and a plurality of sensing the sensed olfactory signal to notify the converter And a plurality of converters for converting a physical olfactory signal into an electrical signal, and an output of a corresponding converter, respectively, in response to a notification of a corresponding detector, and converting the input analog electrical signal into numerical data. Inputs a plurality of encoders, outputs of the plurality of encoders, calculates a molecule concentration for each element, and inputs an output of the calculator, and matches the calculated molecular concentrations for each element in accordance with a transmission format. Characterized in that it comprises a transmitting unit for transmitting.

Description

Olfactory information transmitter

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to communication devices, and more particularly, to an olfactory information transmitter capable of transmitting olfactory information.

Early telecommunication devices used by humans were devices using only hearing functions, such as radio or telephone. The next step was the emergence of televisions, computer monitors, and videophones, devices that could be utilized to the time of day.

However, humans increasingly want to deliver information that is close to reality, and all devices are evolving in response to this demand. Therefore, the image is developed to realize a color or resolution closer to the actual image, and the sound is also developed to reproduce the sound closer to the original sound.

However, the above methods are limited, and therefore, in order to deliver more realistic information, a delivery method capable of stimulating all five senses of people should be realized.

Therefore, in recent years, attempts have been made to develop an imaging device, an information device, or a communication device capable of stimulating other senses in addition to human vision and hearing.

That is, the conventional communication device or video device collects the audio and visual information, which is a physical signal, converts it into an electrical signal, and transmits it to a remote location, and the destination replays the audio and visual information that humans can feel. Was. In addition, the communication device or the video device implements a stereoscopic and high resolution video signal and a stereo signal for a realistic sensing of information on the receiving side, that is, for perfect reproduction of information. However, since the communication device and the image device transmit and receive using only the senses and the hearing of the five senses of the human being, there is no transmission means capable of stimulating other senses.

Accordingly, an object of the present invention is to provide an olfactory information transmitting apparatus capable of transmitting olfactory information in a communication device.

In order to achieve the above objects, the olfactory information transmitting apparatus inputs a plurality of filter units for separating physical olfactory signals for each element and outputs of corresponding filter units, respectively, and detects the input olfactory signals to notify the converter. A plurality of detectors, a plurality of converters for converting a physical olfactory signal into an electrical signal according to the notification of the corresponding detectors, and outputs of the corresponding converters respectively, and inputted analog electrical signals into numerical data Inputs a plurality of encoders to be converted, outputs of the plurality of encoders, calculates a molecule concentration for each element, and inputs an output of the calculator, and converts the calculated molecular concentrations for each element into a transmission format. Characterized in that it comprises a transmission unit for transmitting in accordance with.

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

First, in adding the reference numerals to the components of each drawing, the same components have the same reference numerals as much as possible even if displayed on different drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 illustrates a transmission apparatus having an olfactory information transfer function in a communication device according to the present invention.

The structure of the olfactory information transmitter will be described with reference to FIG. 1.

The filter units 111_1 to 111_5 are configured with different slots, and serve to pass only element molecules of a desired type when the physical olfactory signal strikes the front surface. The detectors 112_1 to 112_5 respectively detect the physical olfactory signals transmitted from the corresponding filter units and notify the converter.

The detection units 112_1 to 112_5 use conventional sensors and detect a physical olfactory signal and notify the conversion unit. The converting units 113_1 to 113_5 convert physical olfactory signals into electrical signals according to notifications of the corresponding sensing units. The encoders 114_1 to 114_5 quantify analog electric signals, which are output signals of the corresponding converters, in binary or other manner, respectively, by sampling or the like. The calculator 115 collects data inputted from the encoders, separates each olfactory signal element, and calculates a concentration.

The signal transmitter 116 formats information according to the transmission format with the information input from the calculator 115 and transmits the data via wired or wireless.

Hereinafter, an operation process according to an embodiment of the present invention will be described.

The present invention can measure the olfactory information to the extent that people feel, convert the quantified numerical data into an electrical signal, and receive the electrical signal at the destination again to accurately reproduce the quantified physical olfactory information input at the source. It is in a ship. Here, the quantification method is based on an average value that people can feel about the smell.

In addition, since the value of the concentration that a person begins to feel may vary depending on the type of smell, if the concentration of the odor is expressed in ppm units, the above-described ppm unit is sensibly quantified and reproduced according to the present invention. It is quite inappropriate.

Thus, the present invention defines a new unit of odor quantification as human sense. For example, a certain kind of odor is designated as the unit of the basic unit of the amount of the minimum amount of odor molecules that can be felt by people 1 meter away. As another example, the fact that people start to smell is defined as one unit of concentration at 90% (in some cases corrected) of a person because there may be variations among individuals.

At this time, the type of smell to be defined is based on the olfactory information signal of the type causing one smell as one element. And the molecule of this smell spreads three-dimensionally, and the density | concentration of 1/10 ³ times of 1 unit is set to 0.1 unit, conversely, 10 ³ times concentration of 1 unit is set to 10 units.

That is, each unit has a difference of 10 ³ times.

In this way, concentrations can be quantified up to more and less odor molecules, and also to define the median of all concentrations in the range, respectively, according to the definition of this value. The odor quantification is applied to different odors, but the average sense of the person is based on the fact that some people may not have normal status or smell. In other words, assuming that there is a blindness, the concentration of 90% of people feels as a standard.

In addition, the smell signal information such as odor gas or poison gas that cannot be smelled by humans does not feel need to be quantified. It can be delivered as it is and can be played back as it is by the receiver. In other words, such a quantification method may be more responsive to human senses than other chemical methods. Therefore, it is possible to reproduce and express the senses received by humans more accurately than the ppm unit, which is a concentration unit. In other words, it detects odor, quantifies, delivers it, and replays it so that a person can feel it.

Referring to FIG. 1, first, the physical olfactory signal information arrives at the front of the detector 112. The olfactory signal passes through the physical filter 111 on the front of the detector 112. The filter unit 111 generates a slit or a hole according to the configuration of the screen in the form of a screen such as an osmotic membrane, and determines the size of the slit or the hole according to the molecules that can be passed. That is, only the molecules of information of a smell smaller than the slit or hole of the filter unit 111 are configured to pass through the filter unit 111 so that only the required molecules are not input to the detector 112. By constructing a filter having a slot (or hole) of size, elemental molecules of various odor information can be extracted.

The detector 112 uses the same principle as a conventional smoke detector or colloid detector. When molecules having odor information are input into the detection unit 112, the detection unit 112 detects this and notifies the conversion unit 113.

The converting unit 113 converts the physical olfactory signal into an electrical signal according to the detected amount of olfactory information, and the encoder 114 samples the converted electrical signal according to the size and quantifies it in binary or other methods.

The calculator 115 collects data input from the encoders 114_1 to 114_5, separates each olfactory signal element, and calculates its concentration.

The transmitter 116 transmits the metered olfactory signal information through wired or wireless. Thus, the electrical value of the quantified signal is transmitted via the transmitter 116.

At this time, a problem arises depending on whether each element of the physical olfactory signal is distinguished. This problem can be solved by configuring the screen of the filter part 111 with various materials. Since molecules of materials that are elements of olfactory signals that can pass through the screen of the filter unit 111 are sensed by different filter units 111, the olfactory signals having molecular structures of various sizes are finally obtained by the calculation unit 115. Separate elements of information can be weighed. That is, they are classified according to the molecular size of the olfactory signal elements, converted into electrical signals, and transmitted.

For example, if you use a filter screen with different hole sizes, you can classify different elements of the olfactory signal information. That is, when the first filter screen 111_1 has a small slit (or hole) and the second filter screen 111_2 is configured to be larger than the slit (or hole) of the first filter screen 111_1, Only molecules smaller than the first slit size pass through the first filter screen 111_1, and only molecules smaller than the second slit size pass through the second filter screen 111_2.

If the amount of the odor element passed through the first filter screen (111_1) and the amount of the odor element passed through the second filter screen (111_2) is electrically converted, the second amount is greater than the amount output through the first filter screen as an electrical signal. More amount is converted to an electrical signal through the filter screen. Subtracting the amount electrically converted through the first filter screen 111_1 from the amount converted through the second filter screen 111_2 to an electrical signal, the difference between the two values is greater than the slit of the first filter screen. This is the concentration value of the odor element smaller than the slit of the second filter screen. In this way, if the concentration value of the odor element passed through the third filter screen 111_3 of the next stage is subtracted, it is larger than the second filter screen 111_2 and smaller than the third filter screen 113_3. The concentration value for the odor component can be calculated. The concentration value of the odor element passed through the N-1 (111_n-1) filter screen and converted into an electrical signal is subtracted from the concentration value of the odor element passed through the N (111_n) th filter screen. The concentration is converted into an electrical signal. This calculation is made in the calculation unit 115, in this way the concentration according to each element can be quantified. The electrical signal output from the calculator 115 is multiplexed by the signal transmitter 116 and transmitted to the outside.

The electrical signal output from the signal transmitter 116 is converted into a wired or wireless signal to enable long-distance transmission. The olfactory information is transmitted in combination with other signals, that is, video signal, audio signal, or other data information, and the receiving side receives this information and inversely separates the video signal, audio signal, data signal, and olfactory signal into each other. By passing through the player, the information transmitted from the transmitter is reproduced correctly.

The quantification of the olfactory information will be described in detail with reference to Table 1 below.

Jasmine is a combination of one element, two elements and four elements (one example), and the concentration of each element is 1 element / 1 unit, 2 elements / 0.5 unit, and 4 elements / 1.2 unit. That is, the transmitting side quantifies and transmits the sensed olfactory information 1 element / 1 unit, 2 elements + 0.5 unit, and 4 elements + 1.2 unit, and the receiving side through the olfactory information generator (flavor generator) prepared for each element / unit provided. The smell corresponding to the received information is reproduced to reproduce the smell of the smell information at the correct concentration.

TABLE 1

In addition, when two or more odors are generated, for example, in a movie scene walking through a pine forest in which jasmine flowers bloom, the two odors must be detected and transmitted at the same time. Assuming that the components of the jasmine fragrance are the same as described above, and that the fragrance fragrance is composed of 2 and 5 elements, the sum of the two olfactory information is composed of 1,2,4,5 elements, and exactly 1 element / 1. It consists of units, 2 elements + 2.8 units, 4 elements + 1.2 units, and 5 elements + 0.1 units. As a result, the transmitter side quantifies the concentrations of the four elements, converts them into electrical signals, and transmits them to the same concentration. do.

As described above, the present invention allows the transmitting side to detect the olfactory information, convert it into an electrical signal, and transmit it, and the receiving side converts the received electrical signal back into physical olfactory signal information. That is, by developing an information device or communication device that can transmit not only visual and auditory but also olfactory information, the receiver can feel the information sent from the sender more vividly.

1 is a block diagram of an olfactory information transmitting apparatus according to an embodiment of the present invention.

Claims (2)

In the olfactory information transmitting device, A plurality of filters for separating physical olfactory signals by each element, A plurality of detectors which respectively input outputs of the corresponding filter units and detect the input olfactory signals and notify the converters; A plurality of converters for converting the detected physical olfactory signals into electrical signals according to notifications of the corresponding detectors; A plurality of encoders for inputting the outputs of the corresponding converters, respectively, for quantifying the input analog electrical signals; A calculator configured to input outputs of the plurality of encoders and calculate a molecular concentration of each element; And a transmitter configured to input an output of the calculator and to transmit the calculated molecular concentration for each element in accordance with a transmission format. The method of claim 1, wherein the calculation of the molecular concentration for each element performed in the calculation unit, Olfactory information transmitting apparatus, characterized in that calculated by subtracting the odor molecular concentration value passing through the filter of the front end of the filter from the odor molecule concentration value passing through the filter.