KR20010002598A - Contact Sensing System for Fingerprints - Google Patents

Abstract

PURPOSE: A fingerprint contact sensor is provided to sense a variation of alternating current frequency, occurring at a fingerprint contact, by using a contact LED(Light Emitting Device), and maintain an idle state when there is no fingerprint contact so that it can enhance a product reliability. CONSTITUTION: A fingerprint contact sensor comprises an inverter(11), a fingerprint input module(12), an amplitude variation sensor(13) and a comparator(14). The inverter(11) outputs selectively a first alternating current or a second alternating current according to an idle state of the fingerprint input module(12). The fingerprint input module(12) maintains the idle state when the first alternating current is supplied from the inverter(11), and generates a photo image when the second alternating is supplied from the inverter(11). The amplitude variation sensor(13) senses the amplitude variation from the second to the first alternating current. The comparator compares the amplitude variation signal with a reference, and if the compared result is more than a set value, it generates a high level signal for making the inverter(11) generate the second alternating current. The fingerprint input module(12) includes a contact LED(12a), a lens(12b) and an image sensor(12c). The fingerprint gets contacted on a surface of the contact LED(12a), then the LED generates a photo image having the fingerprint pattern, the photo image is projected on a surface of the image sensor(12c), and the image sensor(12c) converts the photo signal into the electric image signal.

Description

Contact Sensing System for Fingerprints

The present invention relates to a fingerprint touch sensing device, and more particularly, to a device capable of detecting whether a fingerprint is touched in a fingerprint input device using a touch light emitting device that detects a surface pattern of an object contacted by a simple touch.

As competition between individuals or companies is fierce, locking devices are used to protect their technical or business secrets. The locking device has a password set so that only a predetermined person can use a limited place or object, and the password has recently used fingerprints from simple letters or numbers.

In order to set a password using a fingerprint, a fingerprint input device capable of detecting a fingerprint is required. An element for detecting a fingerprint in the fingerprint input device includes a variable capacitor, an optical or a light emitting body.

A fingerprint input device using a variable capacitor detects a fingerprint by detecting a change in capacitance when a fingerprint is touched, and a fingerprint input device using optical senses a fingerprint by sensing light reflected after incident light.

A fingerprint input device using a light emitter generates an optical image by contact of a fingerprint when a fingerprint is input, and converts the generated optical image into an electrical signal and outputs the converted optical image. The fingerprint input device using the light emitter is the same as the fingerprint input device using optical in that the pattern of the fingerprint is generated as an optical signal, but the fingerprint input device using the light emitter can be thinner than the fingerprint input device using the optical. It is becoming.

However, the fingerprint input device using the light emitter is always in a state in which power is supplied to detect the fingerprint contacted. That is, the fingerprint input device using the light emitter increases power consumption by detecting the fingerprint contacted during the fingerprint contact while the power is supplied, thereby shortening the lifespan of the light emitter emitting light by the contact of the fingerprint in the fingerprint input device. There is a problem of lowering the reliability or shortening the lifespan.

Therefore, in order to solve the above problems, the fingerprint input device detects whether the fingerprint is touched and keeps the fingerprint input device in an idle state when the fingerprint is not input, thereby reducing power consumption. In providing a sensing device.

In addition, another object of the present invention is to increase the product reliability and life of the fingerprint input device by prolonging the life of the light emitting body of the touch light emitting device by supplying power to the touch light emitting device system of the fingerprint input device only when the fingerprint touches.

1 is a block diagram of a fingerprint touch sensing apparatus according to the present invention;

FIG. 2 is a waveform diagram illustrating a change in AC generated in the inverter shown in FIG. 1.

＊ Description of Signs of Main Parts

11: Inverter 11a: Inverter

11b: switch 12: fingerprint input device

12a: contact light emitting element 12b: lens

12c: image sensor 13: amplitude change detection unit

13a: Notch Filter 13b: Inverter

13c: rectifier

In order to achieve the above object, the present invention receives a direct current and converts it into an alternating current to generate a first exchange and a second exchange having a different size and according to whether or not the idle state of the fingerprint input device (idle) And an inverter unit for selecting and outputting a second alternating current and an amplitude of a first alternating current generated by the initial fingerprint contact path inverter unit of the fingerprint input device is changed to generate and output an amplitude detection signal. Receives the amplitude change detection unit and the amplitude detection signal and the reference signal output from the amplitude change detection unit, if the amplitude detection signal is greater than the reference signal to generate a high level (high level) signal to output the second exchange from the inverter unit Provided is a fingerprint touch sensing device, characterized in that configured as a comparator.

(Example)

Hereinafter, a fingerprint touch sensing apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a fingerprint touch sensing apparatus according to the present invention, and FIG. 2 is a waveform diagram showing a change in AC generated in the inverter shown in FIG.

First of all, DC is received and converted into AC to generate first AC2 and AC2 having different sizes, and generate a first AC according to whether the fingerprint input device 12 is idle. Inverter unit 11 for selecting and outputting alternating current AC1 and second alternating current AC2, and first alternating current generated and output by inverter unit 11 during initial fingerprint contact of fingerprint input device 12 When the amplitude of AC1 is changed, the amplitude change detection unit 13 detects the amplitude change signal and generates and outputs the amplitude detection signal, and receives the amplitude detection signal and the reference signal output from the amplitude change detection unit 13 to receive the amplitude detection signal. Is a comparator 14 generating a high level signal to output the second AC2 from the inverter unit 11 when the reference signal is equal to or greater than the reference signal.

The fingerprint input device 12 detects a fingerprint, converts the optical signal into an electrical signal, and generates and outputs the fingerprint image signal. The fingerprint input device 12 that detects a fingerprint is configured such that the contact light emitting device 12a, the lens 12b, and the image sensor 12c are installed at predetermined intervals, respectively.

The fingerprint input device 12 including the touch light emitting device 12a, the lens 12b, and the image sensor 12c generates an optical image signal by a fingerprint pattern when a fingerprint is in contact with the surface of the touch light emitting device 12a. .

At this time, the optical image signal generated by the contact light emitting device 12a is incident on the lens 12c and then transmitted to irradiate the surface of the image sensor 12c, and the image sensor 12c transmits the irradiated optical image signal. It is converted into a signal and generated as a fingerprint image signal.

Subsequently, a predetermined AC voltage is applied to the touch light emitting device 12a to generate a fingerprint image signal from the image sensor 12c. That is, an AC field having a voltage of 50 to 100 V and a frequency of 1 K to 1 MHz is generated so that an electric field is formed between the contact light emitting element 12a and the fingerprint in contact with the fingerprint. Is approved.

In addition, the AC voltage applied to the contact light emitting device 12a is generated by the inverter unit 11, and the inverter unit 11 receives DC (DC) output from a DC generator (not shown) and converts the AC into AC. First and second AC1 and AC2 are generated and output.

The first alternating current AC1 and the second alternating current AC2 output from the inverter unit 11 are generated in different sizes. That is, the first alternating current AC1 is an alternating current for maintaining an idle state of the fingerprint input device 12, and the second alternating current AC2 is a fingerprint contacted by the fingerprint input device 12. It is used as a driving voltage for generating an optical image.

In addition, the first alternating current AC1 and the second alternating current AC2 generated by the inverter unit 12 are selected according to whether or not fingerprint contact is made on the surface of the touch light emitting element 12a and applied to the touch light emitting element 12a. . This will be described separately when the fingerprint is not in contact with the surface of the contact light emitting device (12a) and the fingerprint is in contact as follows.

When the fingerprint is not in contact with the surface of the touch light emitting device 12a, the inverter unit 11 generates and outputs a first alternating current AC1.

Subsequently, the first alternating current AC1 is applied to the touch light emitting device 12a. When the fingerprint contacts the surface of the touch light emitting device 12a, a minimum electric field is formed in the touch light emitting device 12a. It is set to such a size that weak light can be emitted during fingerprint contact.

That is, after a very weak alternating current is applied to the touch light emitting device 12a, a change in amplitude of the first alternating current AC1 may be generated by the fingerprint contact during the initial fingerprint contact. Set to the idle state of.

In the idle state of the fingerprint input device 12, the first AC AC1 in the inverter unit 11 is equal to the waveform "A" shown in FIG. 2.

The waveform " A " represents a waveform of the first AC1 generated in the inverter unit 11 in a state in which no fingerprint is in contact with the surface of the touch light emitting element 12a. When the waveform of the one-AC AC1 does not have a fluctuation such as "A", the amplitude change detection unit 13 is deactivated.

In addition, the switch 12b in the inverter unit 11 is inactivated by the amplitude change detecting unit 13 so that the first alternating current AC1 is supplied to the contact light emitting device 12a in the idle state, thereby providing a fingerprint input device ( 12) to be idled.

Therefore, by keeping the fingerprint input device 12 in an idle state, power consumption may be reduced by minimizing an alternating current applied to the fingerprint input device 12.

Meanwhile, the waveform of the first alternating current AC1 generated by the inverter 11a when the fingerprint is in contact with the surface of the touch light emitting device 12a in the idle state of the fingerprint input device 12 is the waveform shown in FIG. 2. A momentary change occurs, such as "B".

Waveform " B " representing the first alternating current AC1 whose amplitude is modified is in a state where the amplitude is reduced compared to waveform " A ", and the difference between the amplitude of waveform " B " and waveform " A " That is, in the idle state of the fingerprint input device 12, the first alternating current AC1 is generated by transforming the waveform “B” in which the amplitude ΔW is increased from the waveform “A” at the initial instant when the fingerprint is contacted in the waveform “A” state. do.

The first alternating current AC1 whose amplitude is reduced by ΔW from the waveform " A " is reduced and filtered by the notch filter 13a of the amplitude change detection unit 13 before the fingerprint contact, thereby filtering the first AC. AC (AC1) is detected.

The first alternating current AC1 having the reduced amplitude output from the notch filter 13a is received by the inverter 13b and converts the negative signal into a signal having a positive polarity.

At this time, the first alternating current AC1 inverted to the positive polarity is received by the rectifier 13c to convert an AC signal into a DC signal and output the converted AC signal. The DC signal rectified and output from the rectifier 13c is applied to the non-inverting terminal (+) of the comparator 14 as an amplitude sensing signal, and the reference signal V _ref is applied to the inverting terminal (-). The comparator 14 receiving the amplitude detection signal and the reference signal V _ref respectively outputs a high level signal when the amplitude detection signal is greater than the voltage level of the reference signal V _ref .

Subsequently, the reference signal V _ref is set in the comparator 14, and the inverter unit 11 is activated only when the reference signal V _ref is equal to or greater. This is to prevent the fingerprint input device 12 from being activated by the change of the amplitude when the amplitude is changed.

Simple noise may be included in the first AC1 output from the inverter 11a in the idle state of the fingerprint input device 12. The amplitude of the first alternating current AC1 is changed by the noise, and the amplitude change detection unit 13 is activated by the change, and the second alternating current AC2 is output from the inverter unit 11, and the fingerprint input device 12 is changed. Prevents it from being activated.

In addition, the high level signal output from the comparator 14 is applied to the switch 11b of the inverter unit 11. The high level signal applied to the switch 11b switches the state of the switch 11b so that the second alternating current AC2 output from the inverter 11a is supplied to the contact light emitting element 12a. As the second AC2 is supplied to the touch light emitting device 12a, an optical image generated by the contacted fingerprint pattern is generated, and the generated optical image is irradiated to the image sensor 12c through the lens 12b.

The image sensor 12c converts the irradiated optical image into an electrical signal to generate a fingerprint image signal according to the optical image. That is, at the initial moment when the fingerprint contacts the surface of the touch light emitting device 12a, the waveform of the first AC AC1 generated by the inverter 11a is sensed to activate the fingerprint input device 12 in the idle state. And generate an image signal of the fingerprint.

Thereafter, if the fingerprint image is normally generated, the fingerprint image is returned to the idle state again when there is no contact of the fingerprint after waiting a predetermined time. In order to return from the activated state of the fingerprint input device 12 to the idle state, the switch 11b switches so that the first alternating current AC1 is output after waiting for a predetermined time. To this end, the switch 11b uses a switch that operates to automatically toggle.

As described above, when the fingerprint does not come into contact with the surface of the touch light emitting device 12a of the fingerprint input device 12, the alternating current supplied to the touch light emitting device 12a is set to a minimum to bring the fingerprint input device 12 into the idle state. It can be set.

As described above, the present invention can reduce power consumption by setting the fingerprint input device to the idle state in the case of non-contact fingerprint input device using the touch light emitting device, and extend the life of the light emitting device to improve the reliability and life of the product. Prolongs the effect.

Claims (3)

In the fingerprint input device for detecting a fingerprint to generate a fingerprint image signal, An inverter that receives a direct current and converts it into an alternating current to generate first and second exchanges having different sizes, and selects and outputs the first and second exchanges according to whether the fingerprint input device is in an idle state. inverter); An amplitude change detector configured to detect and output an amplitude detection signal when the amplitude of the first alternating current is changed during initial fingerprint contact with the fingerprint input device; And a comparator configured to receive and compare the amplitude detection signal and the reference signal to generate a high level signal when the amplitude detection signal is equal to or greater than the reference signal to output a second alternating current from the inverter unit. Sensing device. The inverter of claim 1, further comprising: an inverter configured to receive a direct current, convert the current into an alternating current, and generate and output first and second interactions having different magnitudes; And a switch configured to receive the first alternating current and the second alternating current, receive a amplitude sensing signal output from the comparator, and select and output a second alternating current. The notch filter of claim 1, wherein the amplitude change detection unit comprises: a notch filter configured to receive and output a first alternating current having a reduced amplitude output from the inverter unit upon initial fingerprint contact with the fingerprint input device; An inverter for receiving the first AC having the reduced amplitude and inverting the polarity to output the inverted polarity; And a rectifier for receiving the amplitude detection signal having the polarity reversed and converting the signal from AC to DC.