JP2014202614A - Infrared detector and detection method of detection object - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an infrared detector capable of more accurately determining the existence of a detection object, and a detection method using the same.SOLUTION: An infrared detector 101 includes: a pyroelectric type infrared sensor 11 that detects a change in the amount of infrared in a detection area 1 to output a detection signal 21; a thermopile type infrared sensor 12 that detects the amount of infrared in the detection area 1 to output a detection signal 22; and a signal processing circuit 16. The signal processing circuit 16 detects the presence of the detection signal 21 to detect the ingress and exit of a detection object 2 to and from the detection area 1 and the existence of the detection object 2 in the detection area 1 based on the state of the detection signal 22 when the detection signal 21 is generated.

Description

  The present invention relates to an infrared detection device for detecting a detection target and a detection method for the detection target.

  At present, an infrared sensor for detecting a human body is used in various scenes such as an automatic door or automatic lighting of an illumination lamp. An infrared sensor is a sensor that can detect the presence or absence of a human body by detecting a slight infrared ray emitted from the human body.

  Conventionally, a pyroelectric element is used for this type of sensor. The pyroelectric element detects a change in the amount of infrared rays in the detection region and outputs an electrical signal indicating the change in the amount of infrared rays. For example, when a person goes in and out of the detection area, the amount of infrared rays in the detection area changes. The pyroelectric element outputs a signal indicating a change in the amount of infrared rays. Therefore, it is possible to detect that a person has entered the detection area or that a person has left the detection area by using a signal from the pyroelectric element.

  When a person is stationary in the detection area, the amount of infrared rays in the detection area does not change. For this reason, the pyroelectric element cannot detect the presence of a person in the detection area. On the other hand, a thermopile sensor or a quantum infrared sensor detects the amount of infrared rays. Therefore, even if a person is stationary in the detection area, the person can be detected by using these sensors.

  The signal from the thermopile sensor or the quantum infrared sensor includes a component depending on the temperature of the detection region as a background component. Background components change due to factors other than humans, such as changes in environmental temperature or changes in solar radiation. For example, when the background component increases, the amplitude (change) of the signal from the thermopile sensor or the quantum infrared sensor decreases. Therefore, even if there is a person in the detection area, it may happen that the person cannot be detected correctly.

  The human body detection device disclosed in Japanese Patent Application Laid-Open No. 7-270545 (Patent Document 1) accurately detects the presence or absence of a human body regardless of a change in temperature in the detection area or a stationary human body in the detection area. The purpose is to judge. According to the above-mentioned document, the differential circuit detects the difference between the levels of positive and negative electric signals output from a plurality of light receiving surfaces of a DC output type infrared detection element (for example, thermopile, thermistor or porometer type). Generate the corresponding differential output. If the differential output exceeds a predetermined threshold value set in advance, the signal processing unit determines that a human body has been detected. For each determination, the signal processing unit continuously outputs the human body detection signal for a preset first off-delay time. Further, the adding circuit adds signals output from the plurality of light receiving surfaces of the DC output type infrared detecting element. When the level of the addition output output from the addition circuit within the first off-delay time is higher than a predetermined level with respect to the level of the addition output before the human body detection signal is output, the signal processing circuit The output of the detection signal is further extended by a preset second off-delay time.

  An infrared sensor and a detection method disclosed in Japanese Patent Laid-Open No. 2009-236751 (Patent Document 2) are intended to detect an object that is stationary within a detection range. According to the above document, the infrared sensor includes a differentiating circuit that obtains a differential value by differentiating a detection signal output from the quantum infrared detection element, and a comparison circuit that compares the differential value with a reference value setting threshold value. , And a first determination circuit and a second determination circuit. When the differential value is larger than the reference value setting threshold, the first determination circuit sets the output value selected based on the output timing of the output location corresponding to the differential value as the reference value. The second determination circuit compares a difference between the set reference value and a subsequent output value input after the output value set as the reference value with a human body detection threshold, and based on the comparison result Determine the presence or absence of a human body.

JP 7-270545 A JP 2009-236751

  According to the configuration described in Patent Document 1, when the human body stops in the detection region, a change exceeding a predetermined threshold does not occur in the differential output. In this case, the signal processing unit cannot detect the human body based on the differential output. Therefore, the human body detection signal is continuously output for a certain time from the time when the differential output exceeds a predetermined threshold value.

  For example, when a person leaves the detection area, it cannot be distinguished from a case where a person enters the detection area or a person who moves within the detection area. For this reason, it is desirable to appropriately adjust the time during which the human body detection signal is output. However, it is not easy to change the time at which the human body detection signal is output in accordance with, for example, the time zone or season.

  In Patent Document 1, a polyethylene condenser lens is used to collect infrared rays. However, since organic materials such as polyethylene have a high emissivity, the infrared radiation of the lens itself becomes noise, and there is a possibility that sufficient performance for human body detection cannot be obtained.

  According to the configuration described in Patent Document 2, the signal of the quantum infrared detection element is differentiated, and based on the differential signal, it is detected that a detection target (for example, a human body) has entered and exited the detection region. When a detection target (for example, a human body) enters and exits the detection area, the intensity of infrared rays received by the quantum infrared detection element changes greatly. Therefore, when the signal of the detection element is differentiated, the differential signal becomes large when the detection target enters and exits the detection region.

  Conversely, when the change in the intensity of infrared rays received by the quantum infrared detection element is small (or hardly changes), even if the signal of the detection element is differentiated, the intensity of the differential signal is small. The signal value of the infrared detection element immediately before the detection of the human body and the signal value of the infrared detection element after the detection of the human body are used as reference values for the amount of change in the signal of the infrared detection element. Therefore, the larger the reference value, the smaller the signal amplitude of the detection element.

  If the presence of a person in the detection area cannot be detected, the presence of the person in the detection area cannot be detected unless a large change in infrared intensity occurs such that the person goes out of the detection area. For this reason, once a state in which the presence of a person in the detection area cannot be detected occurs, it is difficult to return from that state to a state in which it can be normally detected.

  The objective of this invention is providing the infrared rays detection apparatus which can determine presence of a detection target more correctly, and the detection method using the same.

  An infrared detection device according to an aspect of the present invention detects a change in the amount of infrared rays in a detection region, outputs a first signal, detects an infrared amount in the detection region, A second infrared detector that outputs the second signal and a signal processing circuit. The signal processing circuit detects the presence or absence of the first signal, and based on the state of the second signal when the first signal is generated, the detection target enters and exits the detection area, and the detection in the detection area Detect the presence of the target.

  Preferably, the signal processing circuit detects that the detection target enters or leaves the detection region when the first signal is generated and the change amount of the second signal is larger than the threshold value.

  Preferably, the signal processing circuit detects that the detection target has entered the detection area when the second signal changes in the positive direction.

  Preferably, the signal processing circuit detects that the detection target has left the detection area when the second signal changes in a negative direction.

  Preferably, the signal processing circuit detects that the detection target is moving in the detection region when the first signal is generated and the intensity of the second signal is larger than the reference value.

  Preferably, the signal processing circuit detects that the first signal is not generated and is stationary in the detection region when the intensity of the second signal is larger than the reference value.

  Preferably, the signal processing circuit detects that the detection target is moving in the detection region when the first signal is generated and the change amount of the second signal is smaller than the threshold value.

  Preferably, the signal processing circuit detects that the detection target exists immediately before the detection signal when the first signal is not generated and the change amount of the second signal is smaller than the threshold value. If it is, it is detected that the detection target is stationary in the detection area.

  Preferably, when the first signal is not generated and the change amount of the second signal is smaller than the threshold value, the signal processing circuit confirms that the detection target does not exist in the detection area immediately before. If it is detected, it is detected that a state in which no detection target exists in the detection area is continued.

  Preferably, the signal processing circuit resets the threshold value based on the amount of change of the second signal when the second signal rises.

  Preferably, the signal processing circuit resets the threshold value set when the second signal rises based on the amount of change of the second signal when the second signal falls.

  Preferably, the signal processing circuit holds a count value indicating the number of detection targets in the detection area. The signal processing circuit increases the count value when the second signal changes in the positive direction and the amount of change exceeds the threshold value, while the second signal changes in the negative direction. When the change amount exceeds the threshold value, the count value is decreased.

  Preferably, the infrared detection device further includes a case for housing the first and second infrared detection units and the signal processing circuit.

  Preferably, the first infrared detector is a pyroelectric infrared sensor, and the second infrared detector is a thermopile infrared sensor.

  According to another aspect of the present invention, the detection method of the detection target includes a step in which the first infrared detection unit detects a change in the amount of infrared rays in the detection region and outputs a first signal; A step of detecting the amount of infrared rays in the detection region and outputting a second signal; a step of detecting the presence or absence of the first signal; and a second signal when the first signal is generated. And a step of detecting the presence and absence of the detection target in the detection region and the entry and exit of the detection target from the detection region based on the state.

  According to the present invention, it is possible to more accurately determine the presence of a detection target using an infrared detection device.

It is a block diagram of the infrared rays detection device concerning an embodiment of the invention. It is a figure for demonstrating operation | movement of a pyroelectric infrared sensor. It is a figure for demonstrating operation | movement of a thermopile type infrared sensor. It is a figure for demonstrating the detection method of the detection target which concerns on the 1st Embodiment of this invention. It is a flowchart explaining the detection method which concerns on the 1st Embodiment of this invention. It is a figure for demonstrating the visual field range of a pyroelectric type infrared sensor, and the visual field range of a thermopile type infrared sensor. It is the top view which showed the thermopile type infrared sensor which has a some pixel. It is a figure for demonstrating the visual field range of a pyroelectric sensor, and the visual field range of the thermopile sensor which has the several pixel shown by FIG. It is a figure for demonstrating the subject point in the case of detecting a detection target only with a thermopile type infrared sensor. It is a figure for demonstrating the detection method of the detection target which concerns on the 2nd Embodiment of this invention. It is a figure for demonstrating the detection process in case the background of the detection signal from a thermopile type infrared sensor fluctuates. It is a flowchart explaining the detection method which concerns on the 2nd Embodiment of this invention. It is a figure for demonstrating the detection method of the detection target which concerns on the 3rd Embodiment of this invention. It is a flowchart explaining the counting method of the detection target which concerns on the 3rd Embodiment of this invention. It is a flowchart explaining the detection method which concerns on the 4th Embodiment of this invention. It is a figure for demonstrating the detection process which concerns on the 5th Embodiment of this invention. It is a schematic external view of the infrared rays detection apparatus which concerns on the 6th Embodiment of this invention. It is the figure which showed the application example of the infrared rays detection apparatus which concerns on the 6th Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

  In this embodiment, the “detection target” is not particularly limited as long as it emits infrared rays. The reason is basically that the object emits energy corresponding to its temperature from the surface of the object in the form of electromagnetic waves (mainly infrared rays). Accordingly, the detection target includes, but is not limited to, a person, an animal other than a person, a work in a factory, a member, and the like.

  FIG. 1 is a block diagram of an infrared detection device according to an embodiment of the present invention. Referring to FIG. 1, infrared detection apparatus 101 according to an embodiment of the present invention detects detection target 2 in detection area 1. The infrared detecting device 101 includes a pyroelectric infrared sensor 11, a thermopile infrared sensor 12, and a signal processing circuit 16.

  The pyroelectric infrared sensor 11 and the thermopile infrared sensor 12 receive infrared rays 5 emitted from the detection target 2. The pyroelectric infrared sensor 11 detects a change in the amount of infrared light in the detection area 1 and outputs an electrical signal (detection signal 21) indicating the change in the amount of infrared light.

  The thermopile type infrared sensor 12 includes a thermopile (not shown). The thermopile type infrared sensor 12 receives the infrared ray emitted from the detection target 2 and generates an electrical signal (detection signal 22) corresponding to the received infrared ray amount. Each of the detection signals 21 and 22 is an electric signal.

  The signal processing circuit 16 receives the detection signal 21 from the pyroelectric infrared sensor 11 and the detection signal 22 from the thermopile infrared sensor 12 and determines the presence of the detection target 2. Specifically, the signal processing circuit 16 detects the detection object 2 that enters the detection area 1, the detection object 2 that exists in the detection area 1, and the detection object 2 that exits the detection area 1. In addition, when the detection target 2 exists in the detection area 1, the detection target 2 may be moving or may be stationary. In either case, the signal processing circuit 16 can detect the detection target 2. The signal processing circuit 16 outputs a signal indicating the detection result.

  As long as the infrared detecting device 101 according to the embodiment of the present invention includes the pyroelectric infrared sensor 11, the thermopile infrared sensor 12, and the signal processing circuit 16, the specific shape or structure thereof is limited. Is not to be done. For example, the pyroelectric infrared sensor 11, the thermopile infrared sensor 12, and the signal processing circuit 16 may be housed in one case. Alternatively, the pyroelectric infrared sensor 11, the thermopile infrared sensor 12, and the signal processing circuit 16 may be arranged separately and connected by a signal line. Alternatively, the pyroelectric infrared sensor 11 and the thermopile infrared sensor 12 are accommodated in one case, and the signal processing circuit 16 is arranged separately from the pyroelectric infrared sensor 11 and the thermopile infrared sensor 12 and is connected to the signal line. May be connected to each of the pyroelectric infrared sensor 11 and the thermopile infrared sensor 12.

  FIG. 2 is a diagram for explaining the operation of the pyroelectric infrared sensor. With reference to FIG. 2A, first, the detection target 2 enters the detection region 1. Since infrared rays are emitted from the detection object 2, the amount of infrared rays in the detection region 1 increases. Since the amount of infrared rays in the detection region 1 changes, a detection signal 21 is generated from the pyroelectric infrared sensor 11 (see FIG. 1).

  For example, when the intensity of the detection signal 21 exceeds a certain level, it is determined that the detection signal 21 has occurred. Specifically, it is determined that the detection signal 21 is generated when the value of the detection signal 21 exceeds the threshold value V1 and / or when the intensity of the detection signal 21 is lower than the threshold value V2. Note that “t” in FIG. 2 represents time (the same applies to the drawings described below). The absolute value of the threshold value V1 and the absolute value of the threshold value V2 may be the same or different.

  With reference to FIG. 2B, the detection object 2 moves in the detection area 1. For example, the detection target 2 moves in the detection area 1. As the detection object 2 moves, the amount of infrared rays changes in the detection area 1. Therefore, the detection signal 21 is generated from the pyroelectric infrared sensor 11.

  With reference to FIG. 2C, the detection target 2 is stationary in the detection region 1. In this case, the amount of infrared rays does not substantially change in the detection region 1. Therefore, the pyroelectric infrared sensor 11 does not generate the detection signal 21. In other words, the detection signal 21 hardly changes.

  With reference to FIG. 2 (d), the detection object 2 exits from the detection region 1. In this case, the amount of infrared rays in the detection area 1 decreases. Since the amount of infrared rays in the detection region 1 changes, a detection signal 21 is generated from the pyroelectric infrared sensor 11 (see FIG. 1).

  As described above, in the case of (a), (b), and (d) shown in FIG. 2, since the detection target 2 moves, the pyroelectric infrared sensor 11 generates the detection signal 21. However, only the signal output from the pyroelectric infrared sensor 11 determines which of the states shown in FIGS. 2A, 2B, and 2D is the current state. Can not do it.

  Further, when the detection target 2 is stationary, the pyroelectric infrared sensor 11 does not substantially generate the detection signal 21 (the detection signal 21 does not substantially change). For this reason, the stationary detection object 2 cannot be detected only by the detection signal 21 of the pyroelectric infrared sensor 11. That is, when the detection signal 21 of the pyroelectric infrared sensor 11 does not change, a state in which the detection target 2 does not exist in the detection region 1 and a state in which the stationary detection target 2 exists in the detection region 1 Cannot be distinguished.

  FIG. 3 is a diagram for explaining the operation of the thermopile infrared sensor. With reference to FIG. 3A, the detection target 2 enters the detection region 1. Since the detection target 2 emits infrared rays, the amount of infrared rays emitted from the detection region 1 increases. For this reason, the detection signal 22 from the thermopile type infrared sensor 12 (see FIG. 1) rises. As a result, the intensity of the detection signal 22 exceeds the reference value Vref.

  With reference to FIG. 3B, the detection target 2 moves in the detection region 1. Since the detection target 2 exists in the detection region 1, the state where the detection signal 22 exceeds the reference value Vref is continued. However, the change amount of the detection signal 22 at this time is smaller than the change amount when the detection signal 22 rises.

  With reference to FIG. 3C, the detection target 2 is stationary in the detection region 1. Similarly to the case of FIG. 3B, since the detection target 2 exists in the detection region 1, the state where the detection signal 22 exceeds the reference value Vref is continued. The amount of change in the detection signal 22 at this time is smaller than the amount of change in the rise of the detection signal 22.

  With reference to FIG. 3D, the detection target 2 exits from the detection region 1. In this case, since the amount of infrared rays generated in the detection area 1 decreases, the detection signal 22 falls. As a result, the intensity of the detection signal 22 is lower than the reference value Vref.

  As shown in FIG. 3, when the intensity of the detection signal 22 from the thermopile infrared sensor 12 exceeds the reference value Vref, it can be detected that the detection target 2 exists in the detection region 1. Furthermore, based on the amount of change in the detection signal 22, it is possible to distinguish between a state in which the detection target 2 enters the detection region 1 and a state in which the detection target 2 leaves the detection region 1.

  Specifically, as shown in FIG. 3A, when the detection signal 22 from the thermopile infrared sensor 12 rises, it can be detected that the detection target 2 enters the detection region 1. In this case, the detection signal 22 changes in the positive direction. Further, as shown in FIG. 3D, when the output signal of the thermopile infrared sensor 12 falls, it can be detected that the detection target 2 goes out of the detection region 1. In this case, the detection signal 22 changes in the negative direction.

  Note that “changing in the positive direction” means that in a signal measured at a preset time interval, the signal increases more than the signal measured immediately before. Conversely, “changing in the negative direction” means that in a signal measured at a preset time interval, the signal has decreased from the previous signal. In this embodiment, the “change amount” is always a positive value. In order to clarify that the change amount of the detection signal 22 is positive regardless of whether the detection signal 22 changes in the positive direction or the negative direction, the change amount is expressed using an absolute value symbol (||). May show.

  As shown in FIG. 3B and FIG. 3C, when the detection target 2 exists in the detection region 1, the detection signal 22 of the thermopile infrared sensor 12 is in the same state. That is, the detection signal 22 exceeds the reference value Vref, but its change amount is small. Therefore, it is impossible to detect whether the detection target 2 is moving in the detection region 1 or is stationary only by the output signal of the thermopile infrared sensor 12.

  Therefore, in the embodiment of the present invention, the signal processing circuit 16 uses the detection signal 21 from the pyroelectric infrared sensor 11 and the detection signal 22 from the thermopile infrared sensor 12. The detection signal 21 from the pyroelectric infrared sensor 11 indicates that there is a moving detection target 2. From the state of the detection signal 22 when the detection signal 21 is generated, the entry and exit of the detection target 2 in the detection region 1 and the presence of the detection target 2 in the detection region 1 can be detected. Furthermore, when detecting the presence of the detection target 2 in the detection region 1, it may be detected by distinguishing whether the detection target 2 is moving or the detection target 2 is stationary. Each embodiment will be described in detail below.

[Embodiment 1]
FIG. 4 is a diagram for explaining a detection method of a detection target according to the first embodiment of the present invention. With reference to FIG. 4A, the detection target 2 enters the detection region 1. In this case, the pyroelectric infrared sensor 11 generates the detection signal 21. At this time, the detection signal 22 from the thermopile infrared sensor 12 changes in the positive direction. The signal processing circuit 16 determines that the detection target 2 has entered the detection region 1 when the detection signal 21 is generated and the amount of change of the detection signal 22 exceeds the threshold value (dV). That is, the signal processing circuit 16 detects that the detection target 2 has entered the detection region 1.

  With reference to FIG. 4B, the detection target 2 moves in the detection region 1. The pyroelectric infrared sensor 11 generates a detection signal 21. On the other hand, the change amount of the detection signal 22 from the thermopile infrared sensor 12 is small (the change amount of the detection signal 22 is dV or less). However, the detection signal 22 remains in a state where it exceeds the reference value Vref. The signal processing circuit 16 determines that the detection target 2 is moving in the detection region 1 when the detection signal 21 is generated and the detection signal 22 is in a state exceeding the reference value Vref. That is, the signal processing circuit 16 detects that the detection target 2 is moving in the detection area 1.

  With reference to FIG. 4C, the detection target 2 is stationary in the detection region 1. In this case, the pyroelectric infrared sensor 11 does not generate the detection signal 21. On the other hand, the detection signal 22 from the thermopile infrared sensor 12 is in a state exceeding the reference value Vref. The signal processing circuit 16 determines that the detection target 2 is moving in the detection region 1 when the detection signal 21 is not generated and the detection signal 22 is in a state exceeding the reference value Vref. That is, the signal processing circuit 16 detects that the detection target 2 is moving in the detection area 1.

  With reference to FIG. 4 (d), the detection object 2 comes out of the detection area 1. In this case, the pyroelectric infrared sensor 11 generates a detection signal 21. At this time, the detection signal 22 from the thermopile infrared sensor 12 changes in the negative direction. Further, the change amount of the detection signal 22 exceeds the threshold value dV. In this case, the signal processing circuit 16 determines that the detection target 2 has left the detection area 1. That is, the signal processing circuit 16 detects that the detection target 2 has left the detection area 1.

  FIG. 5 is a flowchart for explaining the detection method according to the first embodiment of the present invention. The processing shown in this flowchart is executed by the signal processing circuit 16 at regular intervals, for example. Referring to FIG. 5, when the process is started, in step S <b> 1, signal processing circuit 16 determines the presence or absence of detection signal 21 from pyroelectric infrared sensor 11. When detection signal 21 is output from pyroelectric infrared sensor 11 (YES in step S1), the process proceeds to step S2.

  In step S2, the signal processing circuit 16 determines whether or not the change in the detection signal 22 of the thermopile infrared sensor 12 is large. That is, the signal processing circuit 16 determines whether or not the change amount of the detection signal 22 exceeds the threshold value dV. If it is determined that the amount of change in detection signal 22 of thermopile infrared sensor 12 exceeds threshold value dV (YES in step S2), the process proceeds to step S3.

  In step S <b> 3, the signal processing circuit 16 determines whether or not the change in the detection signal 22 of the thermopile type infrared sensor 12 is a fall of the detection signal 22. That is, the signal processing circuit 16 determines whether or not the detection signal 22 has changed in the negative direction. If the change in detection signal 22 is the fall of detection signal 22 (YES in step S3), the process proceeds to step S4. In step S <b> 4, the signal processing circuit 16 determines that the detection target 2 has left the detection area 1.

  On the other hand, when the change in detection signal 22 is the rise of detection signal 22 (NO in step S3), the process proceeds to step S5. That is, when the detection signal 22 changes in the positive direction, the process proceeds to step S5. In step S <b> 5, the signal processing circuit 16 determines that the detection target 2 has entered the detection area 1.

  If it is determined that the change in detection signal 22 of thermopile infrared sensor 12 is small (the absolute value of the change is less than dV) (NO in step S2), the process proceeds to step S6. In step S <b> 6, the signal processing circuit 16 determines that the detection target 2 has moved in the detection area 1.

  When detection signal 21 is not output from pyroelectric infrared sensor 11 (NO in step S1), the process proceeds to step S7. In step S7, the signal processing circuit 16 determines whether or not the level of the detection signal 22 from the thermopile type infrared sensor 12 is higher than the reference value Vref.

  If it is determined that the level of detection signal 22 is higher than reference value Vref (YES in step S7), the process proceeds to step S8. In step S <b> 8, the signal processing circuit 16 determines that the detection target 2 is stationary in the detection region 1.

  On the other hand, when it is determined that the level of detection signal 22 is lower than reference value Vref (NO in step S7), the process proceeds to step S9. In step S <b> 9, the signal processing circuit 16 determines that the detection target 2 does not exist in the detection area 1.

  When the process in any one of steps S4, S5, S6, S8, and S9 is completed, the entire process is returned to the main routine.

  In step S7, the signal processing circuit 16 may determine whether the immediately preceding determination result (detection result) is a result that the detection target 2 is moving in the detection region 1. When the immediately preceding result is that the detection target 2 is moving in the detection area 1, the signal processing circuit 16 determines that the detection target 2 is stationary in the detection area 1. On the other hand, if the immediately preceding result is a determination result that the detection target 2 has left the detection area 1 or a determination result that the detection target 2 does not exist in the detection area 1, the signal processing circuit 16 1 is determined that the detection target 2 does not exist.

  FIG. 6 is a diagram for explaining the visual field range of the pyroelectric infrared sensor 11 and the visual field range of the thermopile infrared sensor 12. The visual field range corresponds to the detection area of each sensor. Referring to FIG. 6, the visual field range 31 of the pyroelectric infrared sensor 11 and the visual field range 32 of the thermopile infrared sensor 12 overlap to the extent that they substantially coincide. An overlapping portion of the detection areas (field-of-view ranges) of each sensor corresponds to the detection area 1.

  In particular, the viewing angle of the pyroelectric infrared sensor 11 and the viewing angle of the thermopile infrared sensor 12 are preferably substantially the same. As a result, the pyroelectric infrared sensor 11 and the thermopile infrared sensor 12 have the same visual field range, so that it is possible to prevent a range in which only one of the sensors reacts. Therefore, it is possible to prevent an error from occurring in the detection result of the infrared detecting device 101.

  Note that the visual field range 32 shown in FIG. 6 is a visual field range by a thermopile infrared sensor having a single pixel. However, the thermopile infrared sensor may have a plurality of pixels.

  FIG. 7 is a plan view showing a thermopile type infrared sensor having a plurality of pixels. Referring to FIG. 7, in this embodiment, the thermopile infrared sensor includes 16 pixels 12a arranged in 4 rows and 4 columns.

  FIG. 8 is a diagram for explaining the visual field range of the pyroelectric sensor and the visual field range of the thermopile sensor having a plurality of pixels shown in FIG. 7. Referring to FIG. 8, the field-of-view range 32 of the thermopile infrared sensor 12 is divided into 16 regions arranged in 4 rows and 4 columns corresponding to the pixel arrangement. By dividing the field-of-view range 32 of the thermopile type infrared sensor 12 into a plurality of regions, information regarding the position of the detection target 2 in the detection region 1 can be grasped in detail.

  Although only the detection signal 21 output from the pyroelectric infrared sensor 11 can detect the presence of the moving detection target 2, the movement of the detection target 2 from the detection area 1 and the detection area 1 It is not possible to distinguish between the detection object 2 leaving and the movement of the detection object 2 within the detection area 1. However, when the above three types of movements occur, the detection signals 22 from the thermopile infrared sensor 12 are in different states. According to the first embodiment, by using the detection signal 21 from the pyroelectric infrared sensor 11 and the detection signal 22 from the thermopile infrared sensor 12, these states can be distinguished and determined.

  Furthermore, when the detection target 2 is stationary, the pyroelectric infrared sensor 11 does not generate the detection signal 21. For this reason, the pyroelectric infrared sensor 11 alone cannot distinguish between a state where the detection target 2 does not exist in the detection region 1 and a state where the stationary detection target 2 exists in the detection region 1. However, even in these states, the state of the detection signal 22 from the thermopile type infrared sensor 12 is different. Therefore, each state can be distinguished and determined based on the detection signal 22 from the thermopile infrared sensor 12.

[Embodiment 2]
In the second embodiment of the present invention, the presence of the detection target 2 is accurately detected in consideration of the fluctuation of the reference level of the detection signal of the thermopile infrared sensor.

  When detecting whether a detection target exists in a detection area using a thermopile infrared sensor, the reference level of the detection signal of the thermopile sensor infrared sensor is important. The reference level indicates the amount of infrared rays that the thermopile infrared sensor receives from the detection area when there is no detection target in the detection area. That is, the reference level corresponds to the background intensity of the detection signal 22.

  If the temperature in the detection region 1 is constant, the reference level is considered to be substantially constant. However, the temperature in the sensing region 1 can change. The reference level (background intensity) of the detection signal 22 changes as the temperature in the detection region 1 changes. In this case, it may be difficult to accurately detect the presence of the detection target 2.

  FIG. 9 is a diagram for explaining a problem when the detection target is detected only by the thermopile infrared sensor. With reference to FIG. 1 and FIG. 9, for example, when the amount of sunlight irradiated to detection region 1 increases, the temperature of detection region 1 rises, so the amount of infrared rays generated from detection region 1 increases. For this reason, the background intensity (reference level 25) of the detection signal 22 of the thermopile type infrared sensor 12 changes. When the background intensity exceeds the reference value Vref, it is erroneously determined that the detection target 2 exists in the detection region 1 even though the detection target 2 does not exist in the detection region 1.

  In the second embodiment, the presence or absence of the detection target 2 is determined based on the detection signal 21 of the pyroelectric infrared sensor 11 and the state of the detection signal 22 of the thermopile infrared sensor 12. Further, in the second embodiment, when the entry and exit of the detection target 2 are determined, the threshold value of the change amount of the detection signal 22 is reset (reset) based on the determination result.

  FIG. 10 is a diagram for explaining a detection method of a detection target according to the second embodiment of the present invention.

  With reference to FIG. 10A, the detection target 2 enters the detection region 1. In this case, the pyroelectric infrared sensor 11 generates the detection signal 21. A detection signal 22 from the thermopile infrared sensor 12 rises. That is, the detection signal 22 changes in the positive direction. The signal processing circuit 16 determines that the detection target 2 has entered the detection region 1 when the detection signal 21 is generated and the change amount of the detection signal 22 exceeds the threshold value (step value) Step. Further, the signal processing circuit 16 resets the threshold value Step based on the change amount (dV1) of the detection signal 22 from the thermopile infrared sensor 12.

  With reference to FIG. 10B, the detection target 2 moves in the detection region 1. The pyroelectric infrared sensor 11 generates a detection signal 21. On the other hand, although the detection signal 22 from the thermopile infrared sensor 12 changes, the amount of change is smaller than the threshold value Step. In this case, the signal processing circuit 16 determines that the detection target 2 is moving in the detection area 1.

  With reference to FIG. 10C, the detection target 2 is stationary in the detection region 1. In this case, the pyroelectric infrared sensor 11 does not generate the detection signal 21. Furthermore, although the detection signal 22 from the thermopile infrared sensor 12 changes, the amount of change is smaller than the threshold value Step. When the signal processing circuit 16 determines that the detection target exists in the detection region 1 immediately before, the signal processing circuit 16 determines that the detection target 2 is stationary in the detection region 1.

  With reference to FIG. 10 (d), the detection target 2 comes out of the detection region 1. In this case, the pyroelectric infrared sensor 11 generates the detection signal 21. Further, the detection signal 22 from the thermopile infrared sensor 12 falls. That is, the detection signal 22 changes in the negative direction. Furthermore, the change amount of the detection signal 22 exceeds the threshold value Step. In this case, the signal processing circuit 16 determines that the detection target 2 has left the detection area 1.

  Further, the signal processing circuit 16 resets the threshold value Step based on the change amount dV2 of the detection signal 22 from the thermopile infrared sensor 12. The reset threshold value Step is compared with the amount of change of the detection signal 22 when the detection signal 22 from the thermopile infrared sensor 12 rises next time.

  FIG. 11 is a diagram for explaining detection processing when the background of the detection signal 22 from the thermopile infrared sensor 12 varies. Note that the process shown in FIG. 11 is basically the same as the process described with reference to FIG.

  With reference to FIG. 11A, the detection target 2 enters the detection region 1. In this case, the signal processing circuit 16 determines that the detection target 2 has entered the detection region 1 based on the detection signal 21 from the pyroelectric infrared sensor 11 and the detection signal 22 from the thermopile infrared sensor 12. Furthermore, the signal processing circuit 16 resets the threshold Step based on the amount of change in the detection signal 22 from the thermopile infrared sensor 12.

  With reference to FIG. 11B, the detection target 2 moves in the detection region 1. The pyroelectric infrared sensor 11 generates a detection signal 21. As the temperature of the detection region 1 rises, the reference level (background intensity) of the detection signal 22 from the thermopile infrared sensor 12 increases. However, the change amount of the detection signal 22 is smaller than the threshold value Step. The signal processing circuit 16 compares the change amount of the detection signal 22 with the threshold value Step and determines that the detection target 2 is moving in the detection region 1.

  With reference to FIG. 11C, the detection target 2 is stationary in the detection region 1. In this case, the pyroelectric infrared sensor 11 does not generate the detection signal 21. Furthermore, as in the case of FIG. 11B, the amount of change in the detection signal 22 from the thermopile infrared sensor 12 is smaller than the threshold value Step. When the signal processing circuit 16 determines that the detection target exists in the detection region 1 immediately before, the signal processing circuit 16 determines that the detection target 2 is stationary in the detection region 1.

  With reference to FIG. 11 (d), the detection target 2 exits from the detection region 1. In this case, the pyroelectric infrared sensor 11 generates the detection signal 21. Further, the detection signal 22 from the thermopile infrared sensor 12 falls. That is, the detection signal 22 changes in the negative direction. Furthermore, the change amount of the detection signal 22 exceeds the threshold value Step. In this case, the signal processing circuit 16 determines that the detection target 2 has left the detection area 1. Further, the signal processing circuit 16 resets the threshold value Step based on the change amount dV2 of the detection signal 22 from the thermopile infrared sensor 12.

  FIG. 12 is a flowchart for explaining a detection method according to the second embodiment of the present invention. The processing shown in this flowchart is executed by the signal processing circuit 16 at regular intervals, for example. Referring to FIG. 12, when the process is started, in step S <b> 1, the signal processing circuit 16 determines the presence or absence of the detection signal 21 from the pyroelectric infrared sensor 11. When detection signal 21 is output from pyroelectric infrared sensor 11 (YES in step S1), the process proceeds to step S11.

  In step S11, the signal processing circuit 16 determines whether or not the amount of change | dV | of the detection signal 22 of the thermopile infrared sensor 12 is larger than the threshold value Step. If it is determined that | dV |> Step (YES in step S11), the process proceeds to step S12.

  In step S12, the signal processing circuit 16 determines whether or not the change amount dV is smaller than zero. That is, in step S12, the sign of dV is determined. If dV <0, that is, if detection signal 22 changes to negative (YES in step S12), the process proceeds to step S13.

  In step S <b> 13, the signal processing circuit 16 determines that the detection target 2 has left the detection area 1. Next, in step S14, the signal processing circuit 16 resets the threshold value. Specifically, the threshold value Step is set to a value obtained by multiplying a predetermined coefficient α (0 <α ≦ 1) by the absolute value (| dV2 |) of the change amount dV2.

  On the other hand, if dV> 0 in step S12, that is, if detection signal 22 changes positively (NO in step S12), the process proceeds to step S15. In step S <b> 15, the signal processing circuit 16 determines that the detection target 2 has entered the detection area 1. Next, in step S16, the signal processing circuit 16 resets the threshold value. Specifically, the threshold value Step is set to a value obtained by multiplying a predetermined coefficient α (0 <α ≦ 1) by the absolute value (| dV1 |) of the change amount dV1. In step S14 and step S16, the predetermined coefficient α may be the same or different.

  In step S11, when | dV | is less than threshold value Step (NO in step S11), the process proceeds to step S17. In step S <b> 17, the signal processing circuit 16 determines that the detection target 2 has moved in the detection region 1.

  If detection signal 21 is not output from pyroelectric infrared sensor 11 (NO in step S1), the process proceeds to step S18. In step S <b> 18, the signal processing circuit 16 confirms whether or not it is determined in the previous determination process that the detection target 2 exists. For example, the signal processing circuit 16 stores therein data indicating the result of the previous determination process and refers to the data. Thereby, the signal processing circuit 16 confirms whether or not it is determined that the detection target 2 exists.

  When there is a presence determination, that is, in the previous determination, a result of either the entry of the detection target 2 into the detection region 1 or the movement of the detection target 2 in the detection region 1 is obtained (in step S18) YES), the process proceeds to step S19. In step S <b> 19, the signal processing circuit 16 determines that the detection target 2 is currently stationary in the detection area 1. On the other hand, when there is no presence determination, that is, in the previous determination, a result that the detection target 2 exits from the detection region 1 or the detection target 2 does not exist in the detection region 1 is obtained (NO in step S18). ), The process proceeds to step S20. In step S <b> 20, the signal processing circuit 16 determines that the detection target 2 does not exist in the detection area 1.

  When the process in any of steps S14, S16, S17, S19, and S20 is completed, the entire process is returned to the main routine.

  According to the second embodiment, the threshold value can be changed according to the environmental temperature at that time or the temperature of the detection target. Therefore, accurate detection is always possible. For example, in an office area, the temperature can change between daytime and nighttime. Furthermore, the temperature can change depending on the season even in the same time zone. According to this embodiment, a detection target (for example, a human body) can be detected according to the environmental temperature. For this reason, it is possible to prevent erroneous detection and detection omission.

  In addition, you may apply the process of step S11 to S16 to the detection process of 1st Embodiment. That is, in the first embodiment, the process of step S11 may be executed instead of step S2 (see FIG. 5). Moreover, it replaces with the fall determination in step S3, and the process shown to step S12 may be performed. Furthermore, the processes of steps S14 and S16 may be executed after the processes of steps S4 and S5, respectively. That is, the threshold value may be reset based on the change amount of the detection signal 22 from the thermopile infrared sensor 12.

[Embodiment 3]
In the first and second embodiments of the present invention, the detection when the number of detection targets is basically 1 has been described. In the third embodiment of the present invention, a plurality of detection targets can be detected.

  FIG. 13 is a diagram for explaining a detection method of a detection target according to the third embodiment of the present invention. With reference to FIG. 13A, the detection target 2 </ b> A enters the detection region 1. In this case, the signal processing circuit 16 determines that the detection target 2A has entered the detection region 1 based on the detection signal 21 from the pyroelectric infrared sensor 11 and the detection signal 22 from the thermopile infrared sensor 12. The signal processing circuit 16 resets the threshold value Step based on the change amount (dV1) of the detection signal 22 from the thermopile infrared sensor 12.

  Further, the signal processing circuit 16 performs count processing. Specifically, the signal processing circuit 16 holds a count value Count indicating the number of detection targets in the detection area 1. The initial value of the count value Count is zero. When the signal processing circuit 16 determines that the detection target 2A has entered the detection region 1, the signal processing circuit 16 adds 1 to the count value Count. Therefore, in the example shown in FIG. 13A, the count value Count changes from 0 to 1.

  With reference to FIG. 13B, another detection target 2 </ b> B enters the detection area 1. In this case, the pyroelectric infrared sensor 11 generates the detection signal 21. Furthermore, the detection signal 22 from the thermopile infrared sensor 12 rises. The amount of change of the detection signal 22 at this time exceeds the threshold value Step. Thereby, the signal processing circuit 16 determines that another detection target 2 </ b> B has entered the detection area 1. Further, the signal processing circuit 16 adds 1 to the current count value Count. Therefore, Count = 2.

  With reference to FIG. 13C, the detection target 2 </ b> A exits from the detection area 1. In this case, the pyroelectric infrared sensor 11 generates the detection signal 21. Furthermore, the detection signal 22 from the thermopile infrared sensor 12 is lowered. The absolute value of the change amount of the detection signal 22 at this time exceeds the threshold value Step. Thereby, the signal processing circuit 16 determines that one detection target has come out of the detection region 1 (the signal processing circuit 16 cannot distinguish between the detection target 2A and the detection target 2B). Further, the signal processing circuit 16 subtracts 1 from the current count value Count. Therefore, the count value Count changes from 2 to 1. Further, the signal processing circuit executes a reset process for the threshold value Step.

  Referring to FIG. 13 (d), detection object 2 </ b> B comes out of detection area 1. In this case, the pyroelectric infrared sensor 11 generates the detection signal 21. Furthermore, the detection signal 22 from the thermopile infrared sensor 12 is lowered. The amount of change of the detection signal 22 at this time exceeds the threshold value Step. Thereby, the signal processing circuit 16 determines that one detection target has come out of the detection region 1. The signal processing circuit 16 executes a reset process for the threshold value Step.

  Further, the signal processing circuit 16 subtracts 1 from the current count value Count. Therefore, Count = 0.

  The count value Count is an integer of 0 or more. When a negative count is performed while the count value Count is 0, the count value Count is held at 0. That is, after the state shown in FIG. 13D, when the state where the detection target does not exist in the detection region 1 is continued, the count value Count is kept at zero.

  FIG. 14 is a flowchart for explaining a detection target counting method according to the third embodiment of the present invention. Referring to FIG. 12 and FIG. 14, the detection target counting method according to the third embodiment of the present invention performs the processes of S21 to S23 instead of the processes of steps S13, S15, S17, S19, and S20. Prepare. It should be noted that detailed description of the processing of the same step between FIGS. 12 and 14 will not be repeated.

  If dV <0 in step S12 (YES in step S12), the process proceeds to step S21. In step S21, the signal processing circuit 16 adds −1 to the count value Count. That is, the signal processing circuit 16 subtracts 1 from the count value Count. When the process of step S21 ends, in step S14, the signal processing circuit 16 resets the threshold value.

  If dV> 0 in step S12 (NO in step S12), the process proceeds to step S22. In step S22, the signal processing circuit 16 adds 1 to the count value Count. When the process of step S22 ends, in step S16, the signal processing circuit 16 resets the threshold value.

  If there is no detection signal 21 from the pyroelectric infrared sensor 11 in step S1 (NO in step S1), or if | dV | is smaller than the threshold value Step in step S11 (NO in step S11), the process is as follows. Proceed to step S23. In step S23, the signal processing circuit 16 does not change the count value Count. When the process of step S23 ends, the entire process is returned to the main routine.

  According to the third embodiment, it is possible to count the number of detection targets that enter and leave the detection area. Furthermore, the number of detection targets in the detection area can be grasped based on the count value. This function makes it possible to monitor the degree of congestion in the detection area, for example.

The detection area of the infrared detection device according to the third embodiment can be a place used by an unspecified number of people such as a store. In this case, the degree of congestion in the detection area can be monitored. Using the detection result of the infrared detection device according to the third embodiment, for example, it is possible to examine the behavioral characteristics of the user or to guide for avoiding congestion.

[Embodiment 4]
In the fourth embodiment of the present invention, the second embodiment and the third embodiment are combined. That is, the infrared detection device detects the entry of the detection target into the detection area, the exit of the detection target from the detection area, and counts the number of detection targets. Further, the infrared detection device distinguishes that the detection target is moving in the detection area and that the detection target is stationary in the detection area. In this case, the infrared detection device does not change the count value of the detection target.

  FIG. 15 is a flowchart illustrating a detection method according to the fourth embodiment of the present invention. With reference to FIGS. 12 and 15, in the detection method according to the fourth embodiment of the present invention, the process of step S21 is executed between the process of step S13 and the process of step S14. Furthermore, the process of step S22 is performed between the process of step S15 and the process of step S16. Further, the process of step S23 is executed after the processes of steps S17, S19, and S20. Note that the processing in each of the above steps is the same as the processing described in the second and third embodiments, and therefore the following description will not be repeated.

  According to the fourth embodiment, the threshold value can be changed according to the environmental temperature at that time or the temperature of the detection target. Therefore, accurate detection is always possible. Furthermore, the number of detection targets that enter and leave the detection area can be counted. Furthermore, the number of detection targets in the detection area can be grasped based on the count value.

  As in the second embodiment, in addition to the processes in steps S11 to S16, the processes in S21 and S22 may be applied to the detection process in the second embodiment. The case where the processes of steps S11 to S16 are applied to the detection process of the first embodiment has been described in the second embodiment, and thus the subsequent description will not be repeated. Even in such an embodiment, steps S21 and S22 are executed before steps S14 and S16, respectively. As a result, when the detection signal 22 from the thermopile infrared sensor 12 rises and the amount of change of the detection signal 22 exceeds the threshold value Step, the count value increases by one. Further, the threshold value Step is reset based on the change amount of the detection signal 22. On the other hand, when the detection signal 22 from the thermopile infrared sensor 12 falls and the absolute value of the change amount of the detection signal 22 exceeds the threshold value Step, the count value increases by -1. Further, the threshold value Step is reset based on the change amount of the detection signal 22.

[Embodiment 5]
In the fifth embodiment of the present invention, it is possible to prevent detection omission of a detection target. The detection omission means that it is determined that the detection target does not exist even though the detection target exists in the detection area. Note that the detection method according to the fifth embodiment can be combined with any of the detection methods according to the first to fourth embodiments.

  FIG. 16 is a diagram for explaining the detection processing according to the fifth embodiment of the present invention. Referring to FIG. 16A, when the detection target 2 is stationary in the detection region 1, the detection signal 21 from the pyroelectric infrared sensor 11 is not generated and the detection signal from the thermopile infrared sensor 12 is detected. The change amount of 22 is also smaller than the threshold value. Therefore, according to the flowchart shown in FIG. 15, it is determined that the detection target 2 does not exist, and the count value Count does not change (steps S20 and S23).

  When the detection signal 21 from the pyroelectric infrared sensor 11 is generated and the change amount of the detection signal 22 from the thermopile infrared sensor 12 is smaller than the threshold value as shown in FIG. The processing circuit 16 determines that the detection target 2 exists in the detection area 1. Then, when the count value Count is 0, the signal processing circuit 16 adds 1 to the count value Count. Such processing can prevent erroneous determination that the detection target 2 does not exist in the detection region 1.

[Embodiment 6]
FIG. 17 is a schematic external view of an infrared detecting device according to the sixth embodiment of the present invention. Referring to FIG. 17, infrared detection apparatus 201 includes pyroelectric infrared sensor 11, thermopile infrared sensor 12, signal processing circuit 16, and case 18. The pyroelectric infrared sensor 11, the thermopile infrared sensor 12, and the signal processing circuit 16 are housed in a case 18. The case 18 is installed on the ceiling, for example.

  Although not shown in detail, each of the pyroelectric infrared sensor 11 and the thermopile infrared sensor 12 can include an optical system such as a filter or a lens. For example, it is preferable to use a low emissivity material such as Si or Ge for the filter or condenser lens of the thermopile infrared sensor 12. The pyroelectric infrared sensor 11 and the thermopile infrared sensor 12 have substantially the same viewing angle. This overlaps the field of view of each sensor. As a result, it is possible to appropriately detect a detection target (for example, a human body).

  The distance between the pyroelectric infrared sensor 11 and the thermopile infrared sensor 12 only needs to be sufficiently smaller than the detection target 2. Thereby, even if a part of the visual field range is deviated between the pyroelectric infrared sensor 11 and the thermopile infrared sensor 12, the deviation of the visual field range does not significantly affect the detection of the detection target. it can. Although not limited, for example, the distance between the pyroelectric infrared sensor 11 and the thermopile infrared sensor 12 is set to about 1/10 of the size of the detection target.

  Furthermore, the difference in the viewing angle can prevent the detection of the detection target from being greatly affected if the distance to the detection target 2 is L and, for example, in the following relationship. Θp represents the viewing angle of the pyroelectric infrared sensor 11, and θt represents the viewing angle of the thermopile infrared sensor 12.

L × (tan θp−tan θt) <1/10 × (size of detection target)
FIG. 18 is a diagram showing an application example of the infrared detection device according to the sixth embodiment of the present invention. Referring to FIG. 18, a signal from infrared detecting device 201 is sent to dimming device 210. Specifically, the signal from the infrared detection device 201 is a signal output from the signal processing circuit 16. The signal processing circuit 16 can execute the detection method according to any of the first to fifth embodiments.

  The signal from the infrared detection device 201 can indicate the presence or absence of a detection target (a human body in the example of FIG. 18). The light control device 210 controls the illumination device 220 based on a signal from the infrared detection device 201. For example, the light control device 210 turns on the lighting device 220 during a period in which a person is present, and turns off the lighting device 220 when a person is absent.

  As described above, according to the sixth embodiment of the present invention, the pyroelectric infrared sensor 11, the thermopile infrared sensor 12, and the signal processing circuit 16 are accommodated in the single case 18, so that it is compact. An infrared detecting device can be provided. Furthermore, according to the sixth embodiment, the light control device 210 performs the illumination device 220 using the signal from the infrared detection device 201, so that the illumination device 220 is reliably turned on during a period in which a person exists. When there is no person, the lighting device 220 can be turned off. Accordingly, since the time during which the illumination device 220 is lit can be shortened even when no person is present, energy consumption can be saved.

  In the above embodiment, a thermopile type infrared sensor is applied as an infrared sensor for detecting the amount of infrared rays. However, any infrared sensor that detects the amount of infrared light can be used in the embodiment of the present invention in addition to the thermopile infrared sensor. An example of such an infrared sensor is a quantum infrared sensor.

  The embodiment disclosed this time must be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  DESCRIPTION OF SYMBOLS 1 Detection area | region, 2, 2A, 2B Detection object 5 Infrared rays, 11 Pyroelectric type infrared sensor, 12 Thermopile type infrared sensor, 12a Pixel, 16 Signal processing circuit, 18 cases 21, 21, 22 Detection signal, 25 Reference level, 31 32 Field range 101, 201 Infrared detector, 210 Light control device, 220 Illumination device.

Claims (15)

A first infrared detector that detects a change in the amount of infrared rays in the detection region and outputs a first signal;
A second infrared detector that detects the amount of infrared rays in the detection region and outputs a second signal;
Based on the state of the second signal when the first signal is generated by detecting the presence or absence of the first signal, the entry and exit of the detection target with respect to the detection region, and the detection region in the detection region An infrared detection device comprising a signal processing circuit for detecting the presence of a detection target. The signal processing circuit includes:
2. The detection of the detection target entering or leaving the detection region when the first signal is generated and a change amount of the second signal is larger than a threshold value. Infrared detector. The signal processing circuit includes:
The infrared detection device according to claim 2, wherein when the second signal changes in a positive direction, it detects that the detection target has entered the detection region. The signal processing circuit includes:
The infrared detection device according to claim 2, wherein when the second signal changes in a negative direction, the infrared detection device detects that the detection target has left the detection region. The signal processing circuit includes:
The detection of the detection target is moving in the detection region when the first signal is generated and the intensity of the second signal is larger than a reference value. The infrared detection apparatus of any one of Claims. The signal processing circuit includes:
The detection of the stationary state in the detection region when the first signal is not generated and the intensity of the second signal is greater than a reference value. The infrared detection apparatus of Claim 1. The signal processing circuit includes:
The detection target is detected to move in the detection region when the first signal is generated and the change amount of the second signal is smaller than the threshold value. The infrared detection apparatus of any one of 2-4. The signal processing circuit includes:
If the first signal is not generated and the change amount of the second signal is smaller than the threshold value, it can be detected that the detection target exists in the detection area immediately before. The infrared detection device according to claim 7, wherein the detection target detects that the detection target is stationary in the detection region. The signal processing circuit includes:
When the first signal is not generated and the change amount of the second signal is smaller than the threshold value, it is detected that the detection target does not exist in the detection area immediately before. If it exists, the infrared detection apparatus of Claim 7 or 8 which detects that the state in which the said detection target does not exist in the said detection area | region is continued. The signal processing circuit includes:
The infrared detection device according to claim 2, wherein the threshold value is reset based on the amount of change in the second signal when the second signal rises. The signal processing circuit includes:
11. The infrared ray according to claim 10, wherein the threshold value set when the second signal rises is reset based on the amount of change of the second signal when the second signal falls. 11. Detection device. The signal processing circuit holds a count value indicating the number of the detection targets in the detection area,
When the second signal changes in the positive direction and the amount of change exceeds the threshold value, the count value is increased while the second signal changes in the negative direction, The infrared detection device according to any one of claims 2 to 11, wherein the count value is decreased when the amount of change exceeds the threshold value. The infrared detector is
The infrared detection device according to claim 1, further comprising a case that houses the first and second infrared detection units and the signal processing circuit. The first infrared detector is a pyroelectric infrared sensor,
The infrared detection device according to claim 1, wherein the second infrared detection unit is a thermopile infrared sensor. A first infrared detecting unit detecting a change in the amount of infrared rays in the detection region and outputting a first signal;
A second infrared detection unit detecting the amount of infrared rays in the detection region and outputting a second signal;
Detecting the presence or absence of the first signal;
Based on the state of the second signal when the first signal is generated, and detecting the entry and exit of the detection target to and from the detection region, and the presence of the detection target in the detection region, The detection method of the detection target.

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