KR100195765B1 - Position detecting device of shift gears - Google Patents

Abstract

The present invention relates to a vehicle transmission gear risk detection device using a laser beam used in addition to the receiving unit of the remote start device in order to prevent the risk of remote start.

The transmission gear position detecting device includes a code generator (1) for outputting a coded pulse; A coded infrared signal generator (2) for amplifying a code signal to drive an infrared diode and connecting the generated intermittent infrared module to a detection position; A signal receiver 4 mounted at a detection position to separately receive an infrared signal and daylight and external light; A signal compensator 5 for differentially amplifying an infrared code signal and an external light signal in an amplifier to compensate for daylight and external light; Schmitt trigger amplification unit 6 for amplifying the reception code signal and a signal decoding unit 7 for decoding the received signal and outputs an output signal if a predetermined signal.

Description

Infrared transmission gear position detection device

1 is a block diagram of a circuit of the invention.

2 is a detailed circuit diagram of the inventive design.

3 is a timing diagram of an encoder output.

* Explanation of symbols for main parts of the drawings

1: Code generator 2: Infrared signal generator

4: signal receiver 5: signal compensator

6 amplification unit 7 decoding unit

The present invention is to provide a vehicle transmission gear position detection device using infrared rays used in addition to the receiver of the remote start device in order to prevent the risk of remote start.

Vehicles equipped with automatic transmissions can be started only when the gear position is parked or neutral, so there is no problem in safety and convenience when starting remotely even if a remote starter is installed, but vehicles equipped with manual transmissions have neutral gears. Even when you are in the first or reverse position out of position, starting will cause the car to move forward or backward. Since the general remote starter is installed so that the remote start is performed regardless of the state of the gear, when the remote start is in a state such as the first gear of the transmission gear or the reverse gear, the vehicle runs and a safety problem occurs.

In addition, when using a vehicle equipped with a manual gear with a remote control device by using a remote control system, the steering gear must be kept in neutral to leave the driver's seat, thus ensuring safety during remote start. A method of determining a shift position by detecting a signal reflected from a reflector as a photodetector installed in a shift lever for detecting the position is known from Japanese Patent Application Laid-Open No. 2-92733. In addition, it could not be put to practical use because the optical signal could not be coded. In addition, a magnetic or mechanical manual transmission neutral position sensor was provided, but it was difficult to install due to the complicated operation of the manual transmission and various stick positions. There is a lot of heavy vibration of the car directly and the failure rate is high, and when the malfunction causes the unmanned driving state is being avoided its use.

DISCLOSURE OF THE INVENTION It is an object of the present invention to improve the above problems and to provide a highly reliable vehicle transmission gear position detection device that is not subjected to vibration or external influence and does not become an unmanned driving state even when malfunctioned.

The above object of the present invention is achieved by a transmission gear position detecting apparatus using infrared rays capable of linear reflection for non-contact remote position detection.

An object of the present invention is to provide a transmission gear position detecting apparatus using infrared rays capable of linear reflection for non-contact remote position detection.

The present invention includes a code generator for outputting a coded pulse assigned to the input pin in accordance with the selection of the input pin; A coded infrared signal generator for amplifying a code signal to drive an infrared diode and connecting the generated intermittent infrared light to an infrared module to transmit the detected signal to a detection position; A signal receiver for receiving an infrared signal from a detector such as a stick of a transmission and simultaneously separating daylight and external light; A signal compensator configured to differentially amplify an infrared light signal and an external light signal in an amplifier to compensate for daylight and external light; Schmitt trigger amplification unit for amplifying the received code signal; And a signal decoding unit for decoding the received signal and outputting an output signal if it is a predetermined signal; driving the remote starter safely by receiving an infrared signal from the receiver and outputting a specific position detection signal only when the transmission stick is in a neutral state. It can be characterized by.

The present invention will be described in detail with reference to the accompanying drawings.

The present invention includes a code generator (1) for outputting a coded pulse assigned to the input pin in accordance with the selection of the input pin; A coded infrared signal generator (2) for amplifying a code signal to drive an infrared diode and connecting the generated intermittent infrared rays from a laser module to send them to a detection position; A signal receiver 4 for receiving an infrared signal at a detection position such as a stick of the transmission and simultaneously separating and receiving daylight and external light; A signal compensator (5) for compensating daylight and external light by differentially amplifying an infrared light signal and an external light signal in an amplifier; Schmitt trigger amplification section 6 for amplifying the reception code signal and a signal decoding section 7 for outputting an output signal if the received signal is decoded.

The code generator 1 is a PTC PT2262 encoder (EN). When the encoder (EN) addresses A0-A7 are selected to be bit 0, the output signal repeatedly outputs the n-clock cycle high signal and the n-clock cycle low signal as shown in FIG. By this address operation, another code bit 0-bit n can be selected. Likewise, the same code number bit 0-bit in must be selected in order to select the same code as the encoder.

The infrared signal generator 2 drives the infrared generator ID with the DIA ring Q1 and Q2 to obtain the coded infrared rays, and connects the infrared rays from the infrared module IM to the signal receiver 4. In the embodiment, the infrared module IM is aimed to capture the infrared ray IB when the signal receiver 4 attached to the transmission stick ST is in a neutral state of the transmission, and the signal receiver 4 is captured. Infrared light receiving reliability at the reflector was increased by adjusting the infrared module (IM) so that the infrared light receiving radius at about 1cm.

The signal receiver 4 is installed on a stick ST of the transmission, and the incident coded infrared signal is installed to obtain a voltage change value between the collector and the emitter from the phototransistor TR1, and is adjacent to the adjacent. The phototransistor TR2 is installed and configured to separate and receive external light.

The signal compensator 5 differentially amplifies by bridge-connecting the infrared signal separated from the signal receiver and the external light signal of the external daylight and external noise light in the amplifier I1, but the external light signal level is increased by the variable resistor VR. It is made equal to the amount of noise mixed in the infrared signal, and the output potentials of the two phototransistors TR1 and RE2 are bridged and differentially amplified so that the external optical signal is canceled and received by the phototransistor TR1. Amplify only the code signal.

The amplifier 6 is a Schmitt trigger amplifier 12 and amplifies and outputs only the correct pulse when the received signal is unstable.

The signal decoding unit 7 is a PTC PT2272 decoder (DEC). The encoder (DEC) input signal is compared with the code (bit 0-bit n) specified through the address (A0-A7) in the same way as the encoder (EN). This is to start.

Reference numeral C1-C4 denotes a capacitor, R1-R4 denotes a resistor, and D denotes light emitting diodes R13 and R14 which indicate an operating state of the signal decoding unit.

As described above, the present invention installs a signal receiver on a stick of a transmission, receives and amplifies the coded infrared rays at the receiver, and decodes the decoder to drive the driving unit of the remote starter receiver only for the promised signal. It is possible to secure the safety and to use in various devices using the position detection of other transmissions.

Claims (3)

A code generator (1) for outputting a coded pulse in determining a shift position by detecting a signal reflected by a reflector in a light detection force; A coded infrared signal generator (2) for amplifying a code signal to drive an infrared generator, and connecting the generated intermittent infrared rays from the infrared module to transmit them at a detection position; A signal receiver 4 mounted at a detection position to separately receive an infrared signal and daylight external noise light; A signal compensator 5 for differentially amplifying an infrared signal and a noise light signal in an amplifier to compensate for daylight and external noise light; A transmission gear position detecting apparatus using infrared rays comprising a schmitt trigger amplifier (6) for amplifying a received code signal and a signal decoder (7) for decoding a received signal and outputting an output signal if it is a predetermined signal. The transmission gear of claim 1, wherein a pulse coded by an encoder (EN) is output and a position detection signal is output in accordance with a result of signal readout promised by the decoder (DEC), thereby improving reliability of the position detection signal. Position detection device. The method of claim 1, wherein the compensation unit 5 introduces the external daylight and the external noise light from the phototransistor TR2 in the same amount as the noise light reception amount of the infrared signal receiver 4, and the error of the inflow amount is variable resistor VR. It is possible to adjust it, and to bridge the output potentials of the infrared receiver TR1 and the phototransistors TR1 and TR2 to amplify and differentially amplify the external optical signal, and only the code signal received by the receiver 4 infrared receiver TR1. Automobile transmission gear position detection device using infrared rays, characterized in that the amplification.