JP2014124380A - Holder for wearing elements, and bioinformation measurement device using the holder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a holder tightly wearing a plurality of elements onto a head of a subject without causing a positional shift, and to provide a bioinformation measurement device using the holder.SOLUTION: A holder 5 has: a pallet member formed such that the pallet member has a three-dimensional curved face fitted according to an averaged curved surface shape of the head of a subject; a belt member 52 comprising a first portion 52a, second portions 52b and connection portions 52c disposed correspondingly to respective positions of the frontal bone, the occipital bone and the temporal bones in the skull forming the head T of the subject; and connection members 53 each elastically connecting the member 51 and the member 52. Thereby, by placing the member 51 in which light sources 16 and light receivers 21 as elements are mounted, the member 52 and the members 53 on the head T, and fitting a circumference to a circumference of the head T by a circumference adjustment mechanism 52d provided in the member 52, the holder 5 can be tightly worn without causing a positional shift.

Description

  The present invention relates to a holder for holding a plurality of elements and mounting them at a predetermined position on the head of a subject, and a biological information measuring device for measuring information inside the living body using the holder.

  In recent years, as a device that can easily and non-invasively measure the inside of a living body, light is emitted from a light source disposed on the surface of the living body to the inside of the living body, and is reflected and scattered and absorbed inside the living body to reach the living body surface again. Devices that measure the information inside the living body by receiving light are actively proposed. For example, Patent Document 1 below discloses a biological information measuring apparatus that emits light using spread spectrum modulation and measures information in the living body by performing spectrum inverse diffusion demodulation on the light propagated inside the living body.

  This conventional biological information measuring apparatus includes a light emitting unit that emits near-infrared light that has been subjected to spread spectrum modulation using a pseudo-noise sequence, and an electrical signal that corresponds to the received near-infrared light that has been subjected to spread spectrum modulation. And a photodetector for outputting a detection signal by performing spread spectrum demodulation. And according to this biological information measuring device, biological information can be accurately measured in a state where high speed and high S / N ratio are secured.

  By the way, in order to accurately measure biological information using such a light emitting unit and a light detecting unit, a light emitting unit and light detection are performed through measurement on a subject (for example, the head of the subject). It is important that the light emitting unit and the light detecting unit are brought into contact with each other at the same position as the previous measurement in the measurement of another opportunity. For this reason, as described above, when measuring biological information using light that has propagated inside the living body, generally, a holder that holds and contacts the subject with the light emitting unit and the light detecting unit in a predetermined arrangement is provided. Used.

  However, the shape of the head or the like of the subject who is the subject varies depending on, for example, an age difference, a gender difference, or an individual difference. For this reason, in a state where the holder to be used does not correspond to the size or shape of the subject's head or the like, a situation in which the holder cannot be sufficiently fixed to the subject (the subject's head or the like) may occur. In this way, when the holder cannot be firmly fixed and attached to the subject (the subject's head or the like), the light emitting unit and the light detecting unit integrally assembled with the holder are the subject. The light emitting part and the light detecting part cannot be kept in contact with a predetermined position of the subject with a predetermined arrangement. As a result, accurate measurement at the measurement target position becomes impossible. In addition, if the holder is to be attached with a strong force in order to firmly fix the holder to the subject (the subject's head, etc.), the light emitting part and the light detecting part can be maintained in contact with each other at a certain position. Become. However, when the subject is the head of the subject or the like, the subject may feel a strong pressure and become difficult to measure for a long time as the holder is attached with a strong force.

  Regarding such a holder, more specifically, fixing of the light emitting unit and the light detecting unit to the subject (particularly the head of the subject), for example, in Patent Document 2 below, it is easy to match the shape of the subject. An optical biometric apparatus and a holder that increase the amount of information from a subject are disclosed. In this conventional optical biometric apparatus and holder, holes formed in each of the two holder parts are overlapped, and a plurality of holder parts are connected by attaching a socket inserted into the overlapped hole with a nut, thereby forming a net-like shape. It is designed to form a body. In this conventional optical biometric apparatus and holder, a light transmitting probe or a light receiving probe is attached to the socket, and a portion in which a plurality of holder parts are joined by adjusting the screw tightening of the socket and the nut. The angle in the tangent plane of the surface of the measuring object can be arbitrarily adjusted. Further, in this conventional optical biometric apparatus and holder, since the holder part is flexible, the holder can be deformed and mounted in accordance with the curvature of the head.

  Furthermore, for example, Patent Document 3 below discloses a head mounted holder for biological light measurement in which the light irradiation / light detection module is securely attached to the scalp and does not give an excessive feeling of pressure to the subject. In this conventional head mounted holder for biological light measurement, the light irradiation module and the light detection module each have a contact portion that contacts the scalp of the subject at the tip, and the light guide is formed by exposing the tip. It has a contactor and a package with the contactor attached below. And a contactor is fixed to the lower part of a package via an elastic body, and a package is fixed to the inner upper wall of the insertion hole provided in the holder via the serial structure of an elastic body and a viscoelastic body. .

JP 2002-248104 A JP 2004-313741 A JP 2009-45281 A

  By the way, in the holder described in the said patent document 2, since it is comprised from the holder component which has flexibility, the light transmission probe or element as an element with respect to a measuring object, specifically a test subject's head, or It is possible to cover the holder itself with the light receiving probe assembled, and it can be easily mounted. However, in order to maintain this ease of mounting, the holder itself cannot be fixed to the subject's head. For this reason, it is difficult to always fix the holder itself (that is, the light transmitting probe or the light receiving probe) to the subject's head through measurement without being displaced. Moreover, in the head mounted holder for biological light measurement described in the above-mentioned Patent Document 3, when the package (holder) is not flexible, it does not conform to the shape of the subject's head. In this case, it is difficult to properly contact the contactors as all the elements with the subject's scalp, and it is extremely difficult to firmly fix the contactors without being displaced with respect to the subject's head.

  The present invention has been made in order to solve the above-described problems, and an object of the present invention is to use a holder for securely mounting a plurality of elements without causing a positional shift with respect to the subject's head, and the holder. It is to provide a living body information measuring apparatus.

  In order to achieve the above object, the present invention is characterized in that, in a holder for holding a plurality of elements and mounting them at predetermined positions on the subject's head, a plurality of through holes for holding the plurality of elements, respectively. And a pallet member that is a thin and thin plate shaped so as to have a three-dimensional curved surface that matches the curved shape of the averaged head, and the frontal bone of the skull that forms the head of the subject. A first portion arranged circumferentially corresponding to the position, a second portion arranged circumferentially corresponding to the position of the occipital bone in the skull, and arranged corresponding to the position of the temporal bone in the skull A belt-like belt member that is fixed to the subject's head in a circumferential shape, and is provided on the belt member. The belt member comprises a connection portion that connects the first portion and the second portion to each other. The subject It is comprised including the circumference adjustment mechanism which adjusts the circumference of the said belt member according to the circumference of a head, and the string-like connection member which expands and contracts the said pallet member and the said belt member. It is in.

  In this case, the pallet member is formed corresponding to each part of the head of the subject wearing the plurality of elements, and the averaged head that is different for each part of the head It may be formed so as to have a three-dimensional curved surface that matches the curved surface shape.

  In these cases, it is preferable to provide a guide member for holding the plurality of elements in a state preset on the head of the subject with respect to the plurality of through holes formed in the pallet member. In this case, the guide member may hold at least the plurality of elements toward a predetermined reference point on the subject's head.

  In these cases, the connecting portion of the belt member has a curve formed so as to bypass the rear portion of the pinna of the subject's ear, and the first portion and the second portion are connected to each other. It is good to connect each other.

  In these cases, the pallet member is preferably provided with an adjusting portion for finely adjusting the connection state with the connection member in the vicinity of the connection position with the connection member. Furthermore, in these cases, the circumferential length adjusting mechanism connects the second portions positioned at both ends of the belt member formed in a string shape so as to overlap each other and relatively connects the second portions overlapped with each other. The belt member may be slid in the opposite direction to adjust the circumference of the belt member in accordance with the circumference of the subject's head. In this case, it is preferable that the assertion adjustment mechanism includes an adjustment dial that is rotated so as to slide the second portions of the belt member that are overlapped with each other in the opposite direction.

  Another feature of the present invention is that a biological information measuring device that detects light propagated through a living body and measures biological information of the detected light includes any one of the holders described above. A light source having a light emitting element detachably held on the pallet member of the holder is caused to emit light based on a predetermined drive signal, and near infrared light having a different specific wavelength is emitted inside the head of the subject. Near-infrared light that has been emitted from the light emitting portion and propagated through the inside of the subject's head via a light emitting portion and a light receiver having a photoelectric conversion element that is detachably held on the pallet member of the holder And a light detection unit that outputs an electrical detection signal related to the metabolism of the living body corresponding to the light intensity of the near-infrared light detected, and the light emitting unit and the light detection unit Centralized control of operation There is also the fact that a control unit for calculating biological information based on the electrical detection signal outputted from the light detection unit.

  In this case, the light source of the light emitting unit includes at least a case body that is electrically conductive and grounded, a case cap that is at least electrically conductive and is assembled to the case body, and the specific wavelength. The light-emitting element is housed in a case that has optical transparency and electrical conductivity and is electrically connected to the case body and emits light. A case body that is at least internally conductive and grounded, a case cap that is at least internally conductive and is assembled to the case body, and an optical device for a specific wavelength emitted from the light emitting portion. The photoelectric conversion element and the light are disposed in a case that is transparent and has electrical conductivity and is electrically connected to the case body and includes a window portion that receives light. An amplification circuit that amplifies the electrical detection signal output from the conversion element and outputs the amplified electrical detection signal with an output impedance smaller than the output impedance of the photoelectric conversion element is housed and configured. And good. In this case, the inside of the case main body and the inside of the case cap are formed by a strike-plated nickel (Ni) layer and an electrolessly plated copper (Cu) layer or gold (Au) layer on the nickel (Ni) layer. A transparent conductive film mainly composed of indium-tin oxide (ITO), zinc oxide (ZnO) or niobium oxide (NbO) is formed in the window portion, The thin film conductive layer and the transparent conductive film may be electrically connected.

  In these cases, the biological information calculated by the control unit includes, for example, oxygenated hemoglobin concentration length change combined with oxygen in the blood vessel of the subject's head, and reduced hemoglobin concentration not combined with oxygen. It is good that it is biological information related to the activity of the subject in the brain calculated based on information representing a long change.

  Further, in these cases, the light emitting unit has a spread spectrum modulation means for performing spread spectrum modulation on the predetermined drive signal, and the light detection unit demodulates the electrical detection signal by despreading the spectrum. It is good to have a demodulation means. In this case, the spread spectrum modulation unit of the light emitting unit includes a spread code sequence generation unit that generates a spread code sequence for performing spread spectrum modulation on the predetermined drive signal using a first frequency, and the spread code sequence generation unit The first modulation means for spectrum-spreading the predetermined drive signal using the spreading code sequence generated by the step S1 and outputting a primary modulation signal, and the second frequency that is twice the first frequency Second modulation means for modulating the primary modulation signal output by the first modulation means and outputting a secondary modulation signal, wherein the demodulation means of the photodetecting section is a signal band of the electrical detection signal Signal component removing means for removing and outputting signal components at DC and frequencies near DC, and signal components at or above the second frequency, and the near infrared light is the head of the subject. Signal conversion for converting the electrical detection signal output by the signal component removal means into a digital signal using a third frequency that is twice the second frequency, taking into account the delay associated with propagation in the interior Primary demodulation by demodulating the digital signal converted by the signal conversion means using the second frequency taking into account the delay associated with propagating the near-infrared light inside the subject's head A first demodulating means for outputting a signal, and a spectrum despreading of the primary demodulated signal using the spreading code sequence in consideration of a delay caused by propagating the near infrared light inside the head of the subject. It is preferable to have a second double tone means for outputting a secondary demodulated signal. In this case, the second frequency is preferably matched with an effective detection bandwidth in which the light detection unit can effectively detect near-infrared light that has propagated inside the subject's head.

  In these cases, the light emitting unit acquires the predetermined drive signal supplied with a predetermined time interval, and the light source sequentially emits light based on the acquired predetermined drive signal, The near-infrared light having the different specific wavelengths may be emitted sequentially with the predetermined time interval.

  Further, in these cases, the light emitting unit includes frequency division multiplexing modulation means for generating a modulation signal by frequency division multiplexing modulation of the predetermined drive signal, and the light detection unit includes the electrical detection signal. It is preferable to have a double tone means for frequency-division multiplexing demodulation.

  According to these, the holder for holding and mounting a plurality of elements on a predetermined position of the subject's head includes the pallet member, the belt member, the circumferential length adjusting mechanism, and the connecting member. Can do.

  The pallet member is hard and thin plate-like, and has propagated through the subject's head with a plurality of elements, specifically, a light source that emits light having a specific wavelength (near infrared light) and a specific wavelength. A plurality of through-holes for holding light receivers that receive light (near-infrared light) are formed, and a three-dimensional curved surface that matches the curved shape of the averaged head is formed. . In this way, since the pallet member is shaped to have a three-dimensional curved surface that matches the curved shape of the head, it can be applied to a predetermined position of the subject's head, such as the frontal lobe, occipital lobe, temporal lobe, parietal lobe, etc. All of the plurality of elements (light source and light receiver) to be held can be appropriately brought into contact with the corresponding measurement region (scalp).

  The belt member includes a first portion arranged circumferentially corresponding to the position of the frontal bone in the skull, a second portion arranged circumferentially corresponding to the position of the occipital bone in the skull, and the temporal bone in the skull And a connecting portion that is arranged corresponding to the position of the first portion and the second portion. Thereby, more specifically, the belt member can be firmly fixed to the subject's head with respect to a predetermined circumferential position based on the skull forming the subject's head. Therefore, the pallet member connected to the belt member via the connecting member can be fixed securely to the subject's head, more specifically, to the predetermined measurement region without causing any positional deviation. Further, since the belt member can be fixed with reference to the skull of the subject, for example, even when the holder is mounted at the time of measurement of another opportunity, the holder, that is, the belt, is positioned at substantially the same position as the mounting position at the previous measurement. A member can be mounted. Therefore, the pallet member connected to the belt member, more specifically, the elements (light source and light receiver) held by the pallet member are arranged with high reproducibility and extremely accurately with respect to the measurement region in the subject's head. can do.

  Here, the connection part of the belt member can be formed with a curve formed so as to bypass the rear part of the pinna of the subject's ear. This facilitates positioning when the belt member is attached to the head of the subject, and as a result, the elements (light source and light receiver) held by the pallet member are reproduced with respect to the measurement region in the subject's head. It can be arranged with good performance and extremely high accuracy.

  The circumference adjustment mechanism is provided on the belt member, and adjusts the circumference of the belt member in accordance with the circumference of the head of the subject. Thereby, when mounting | wearing a test subject's head with a belt member, it can adjust to the circumference matched with the circumference of a test subject's head, and can be fixed firmly. Here, the circumference adjustment mechanism can have an adjustment dial that is rotated to slide the second parts that are overlapped with each other in the opposite direction, so that the circumference of the belt member can be very easily achieved. Can be adjusted according to the circumference of the head of the subject.

  The connecting member extends and contracts the pallet member and the belt member. As described above, the connecting member expands and contracts to connect the pallet member and the belt member, so that individual differences among the subjects can be absorbed and the pallet member can be firmly connected to the belt member. Therefore, the pallet member can be firmly fixed to the head of the subject, more specifically, without causing a positional shift with respect to a predetermined measurement region.

  In the biological information measuring apparatus using the holder that can fix the element (light source and light receiver) to the predetermined measurement region in the subject's head without causing any positional deviation in this manner, Can emit near-infrared light having a specific wavelength accurately from a predetermined position into the measurement region, and the receiver can detect near-infrared light having a specific wavelength propagated in the measurement region accurately at the predetermined position. can do.

  In this case, in the biological information measuring apparatus, the light emitting unit is electromagnetically shielded, for example, a spread spectrum modulated drive signal or a predetermined drive signal supplied with a predetermined short time interval. Alternatively, near-infrared light having a plurality of specific wavelengths can be emitted toward the inside of the subject's head by emitting light from the light source based on the frequency division multiplex modulated drive signal. On the other hand, the light detection unit receives near-infrared light propagating through the living body in an electromagnetically shielded state, and the received near-infrared light, that is, a pole attenuated along with propagation inside the subject's head. An electrical detection signal related to biological information can be output with low impedance corresponding to the light intensity (light quantity) of weak near-infrared light. Here, the light emitting unit emits a light source based on a drive signal (modulation signal) obtained by subjecting a predetermined drive signal to spread spectrum modulation or frequency division multiplex variation, and directs near infrared light having a plurality of specific wavelengths into the living body. In this case, the light detection unit can perform spectrum despread demodulation or frequency division multiplexing modulation on the electrical detection signal. Then, based on the electrical detection signal, biological information, for example, oxygenated hemoglobin concentration length change and reduced hemoglobin concentration length change, oxygenated hemoglobin concentration length change and reduced hemoglobin concentration length change in the blood vessel of the subject's head The total hemoglobin concentration length change that can be calculated as the sum of the above, the pulse wave that changes with the blood flow, or the oxygen saturation can be calculated.

  In these cases, the element (light source and light receiver) is detachably assembled to the pallet member of the holder, and the engagement protrusion formed on the element (light source and light receiver) is displaced in the axial direction. A ring member having a groove portion to be inserted along with the groove portion of the ring member, and the groove portion of the ring member being rotated after the groove portion of the ring member has inserted the engagement protrusion along with the displacement in the axial direction. A latch mechanism including a coil spring that is in a compressed state between the ring member and the pallet member when the other part is engaged can be provided. In this case, a holding portion for holding the coil spring can be formed on the ring member, and the coil spring can be integrally assembled with the ring member. In these cases, the elements (light source and light receiver) are arranged on the pallet. With the ring member of the latch mechanism and the engaging protrusion formed on the element (light source and light receiver) engaged with each other in a state of being inserted through the through hole formed in the member, the element (light source) And a light receiver) can be assembled. In these cases, the elements (light source and light receiver) can be alternately arranged and assembled in a matrix on the pallet member of the holder.

  According to these, it is possible to attach and detach the elements (light source and light receiver) to and from the pallet member very easily using the latch mechanism that includes the ring member and the coil spring. More specifically, the ring member of the latch mechanism is rotated to form the element (light source and light receiver) in a state where the element (light source and light receiver) is inserted through the through hole formed in the pallet member. The elements (light source and light receiver) can be assembled to the pallet member of the holder by engaging the engagement protrusions. Thereby, for example, even when it is necessary to change the arrangement of the elements (light sources and light receivers) according to the purpose of measurement, the ring member of the latch mechanism is aligned with, for example, the groove and the engaging protrusion. The element (light source and light receiver) together with the latch mechanism can be removed (removed) from the pallet member together with the rotation mechanism, and the element (light source and light receiver) inserted into the through hole of the pallet member can be removed. As described above, the elements (light source and light receiver) can be attached (attached) to the pallet member together with the latch mechanism only by attaching the latch mechanism. Therefore, the elements (light source and light receiver) can be attached to and detached from the pallet member very easily and quickly.

  Further, by attaching the elements (light source and light receiver) to the pallet member using the latch mechanism, the coil spring constituting the latch mechanism can adjust the amount of displacement of the elements (light source and light receiver) in the axial direction. it can. Thereby, the favorable contact state with respect to the test subject's head (scalp) of an element (a light source and a light receiver) can be maintained.

It is a block diagram which shows the outline of the biological information measuring device common to embodiment and the modification of this invention. It is a block diagram which shows schematically the structure of the light-projection part of FIG. It is a schematic sectional drawing which shows the structure of the light source of FIG. FIG. 2 is a block diagram schematically showing a configuration of a light detection unit in FIG. 1. FIG. 5 is a schematic cross-sectional view showing the configuration of the light receiver in FIG. 4. FIG. 5 is a schematic electric circuit diagram of the amplifier of FIG. 4. FIG. 2 is a block diagram schematically showing a configuration of a controller in FIG. 1. It is a schematic diagram which shows the structure of the holder of FIG. FIG. 9 is a schematic diagram illustrating a configuration of a circumference adjustment mechanism in FIG. 8. FIG. 9 is a schematic diagram illustrating a mounting change example of the holder of FIG. 8. FIG. 9 is a schematic cross-sectional view illustrating a configuration of a guide member assembled in a through hole formed in the pallet member of FIG. 8. It is a schematic sectional drawing which shows the structure of the latch mechanism of FIG. FIG. 9 is a schematic partial cross-sectional view for explaining an assembled state of a pallet member, a latch mechanism, and a light source or a light receiver in the holder of FIG. 8. It is the figure which extracted and showed a part of arrangement | positioning of the light source of the light-projection part and the light receiver of a photon detection part at the time of applying a biometric information measurement apparatus to the measurement of the biometric information in a brain. It is a schematic diagram for explaining Lambert-Beer's law. It is the graph which showed roughly the change of the molecular extinction coefficient with respect to the wavelength of oxygenated hemoglobin and reduced hemoglobin. It is sectional drawing which showed roughly the scattering state of the light inside a head. The light reflection state inside the head, (a) is a cross-sectional view schematically showing a case where the distance to the reflection position is short, and (b) is a case where the distance to the reflection position is long. It is the schematic which shows the structure of the exit window of the light source which concerns on the modification of this invention, and the entrance window of a light receiver. It is a schematic sectional drawing which shows the structure which provided the optical filter in the incident window of the light receiver concerning the modification of this invention. It is the graph which showed roughly the change of the molecular extinction coefficient with respect to the wavelength according to the difference of oxygen saturation.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram schematically showing a configuration of a biological information measuring device S according to an embodiment of the present invention. As shown in FIG. 1, the biological information measuring apparatus S has a plurality of light emitting units 1 that generate light having a specific wavelength, and after the light emitted from the light emitting unit 1 propagates while reflecting inside the living body. And a plurality of light detectors 2 for detecting the light of the light. In addition, the biological information measuring device S has a microcomputer composed of a CPU, ROM, RAM, timer, and the like as main components, and comprehensively controls the operation of the light emitting unit 1 and the light detecting unit 2 and related to the metabolism of the living body. A controller 3 that calculates and outputs biometric information to be output, and a display unit 4 that displays the calculated biometric information in a predetermined manner. Furthermore, the biological information measuring device S in the present embodiment has a plurality of light emitting units 1 (more specifically, a light source 16 to be described later) and a plurality of light detecting units 2 (more from the subject's head, which is the subject). Specifically, a holder 5 for holding and appropriately mounting a light receiver 21, which will be described later, and a light emitting unit 1 (more specifically, a light source 16 described later) and a light detecting unit 2 (from Specifically, it includes a latch mechanism 6 for assembling a light receiver 21) to be described later.

  The plurality of light emitting units 1 each generate light having different specific wavelengths. In the following description, the light emitting unit 1 is exemplified and configured to generate light having two specific wavelengths. However, the number of specific wavelengths of the light emitted from the light emitting unit 1 is not limited to this, and the light emitting unit 1 is implemented so as to generate light having one specific wavelength, or has three or more specific wavelengths. It can be implemented to generate light. In particular, by increasing the number of specific wavelengths emitted from the light emitting unit 1, it is possible to sufficiently ensure the quantitativeness of biological information obtained as described later.

  The plurality of light emitting sections 1 in the present embodiment emit light having a specific wavelength by performing spread spectrum modulation. For this reason, as shown in FIG. 2, each light emitting unit 1 uses, for example, a spread code sequence to generate a PN (Pseudorandom Noise) sequence consisting of “+1” and “−1” having a length of 65536 bits. A code sequence generator 11 is provided. The spreading code sequence generator 11 generates, for example, a Hadamard sequence, an M sequence, or a Gold code sequence as a PN sequence.

  The Hadamard sequence, the M sequence, or the Gold code sequence described above is the same as that used for general spread spectrum modulation, and therefore a detailed description of the generation method is omitted. Keep it. The Hadamard sequence is a sequence obtained by extracting each row or each column of the Hadamard matrix composed of “+1” and “−1”. The M series uses a shift register in which n stages of 1-bit registers for storing the state of “0” or “+1” are arranged, and an exclusive OR of a value fed back from the middle of the shift register and a value in the last stage Is a binary sequence obtained by connecting to the first stage. However, in order to make this binary sequence a PN sequence, level conversion is performed to convert the value “0” into “−1”. The Gold code sequence is basically a code sequence obtained by preparing two types of M sequences and adding them. For this reason, the Gold code sequence is a matrix that can significantly increase the number of sequences compared to the M sequence. As a feature of these sequences, different sequences have the property of being orthogonal to each other, and by performing a product-sum operation, it can be mentioned that the correlation becomes “0” except for self. .

  The spread code sequence generator 11 receives a clock frequency 2 f supplied from a clock generator 32 (described later) provided in the controller 3. Then, based on the input clock frequency 2f, the spread code sequence generator 11 generates a PN sequence in which the generation frequency of the PN sequence, in other words, the chip rate corresponding to the minimum generation interval of the PN sequence is f or less.

  In this way, the PN sequence generated by the spread code sequence generator 11 is output to the controller 3 and also to the first multiplier 12. The first multiplier 12 takes the product of the DC signal output from the baseband output unit 13 and the PN sequence supplied from the spread code sequence generator 11 and performs spread spectrum modulation on the DC signal. In the following description, the spread spectrum modulated DC signal is referred to as a primary modulation signal.

  This primary modulation signal is output to the second multiplier 14. The second multiplier 14 receives the primary modulation signal and also receives the clock frequency 2 f supplied from the clock generator 32 of the controller 3. Then, the second multiplier 14 modulates the input primary modulation signal with the clock frequency 2f. Thus, by modulating the primary modulation signal with the clock frequency 2f, the modulated primary modulation signal has the strongest signal strength at the frequency f. In the following description, the modulated primary modulation signal is referred to as a secondary modulation signal.

  As described above, the secondary modulation signal modulated by the second multiplier 14 is output to the light source driver 15. The light source driver 15 supplies a predetermined driving voltage to the light source 16 based on the secondary modulation signal, and drives (emits light) the light source 16. As shown in FIG. 3, the light source 16 includes a light emitting element 16b accommodated in the case 16a and an emission window 16c for emitting light from the light emitting element 16b.

  The case 16a is formed of a non-conductive material having excellent insulating properties, for example, a resin material such as ABS, and includes a cylindrical case body 16a1 and a case cap 16a2. The case main body 16a1 accommodates the light emitting element 16b, and the case cap 16a2 seals the accommodated light emitting element 16b in the case main body 16a1, for example, by screwing. Further, the inner peripheral side of the case main body 16a1 and the case cap 16a2 and the contact portion (screwed portion) between the case main body 16a1 and the case cap 16a2 are made of a metal material having excellent conductivity by, for example, electroless plating. A thin film conductive layer 16a3 is formed. Here, the thin film conductive layer 16a3 is, for example, a strike-plated nickel (Ni) layer, and a copper (Cu) layer or gold (Au) having a thickness of about 10 μm electrolessly plated on the nickel (Ni) layer. It is good to form from a layer. The thin film conductive layer 16a3 having excellent conductivity formed on the inner peripheral side is grounded via an electrode or the like not shown.

  The light emitting element 16b is, for example, a semiconductor laser or a light emitting diode, and an anode electrode and a cathode electrode (not shown) are connected to each other. The light emitting element 16b emits near-infrared light (hereinafter referred to as modulated light) having a specific wavelength within the wavelength range of 600 to 1500 nm. Here, in the following description, it is assumed that the light emitting element 16b constituting the light source 16 emits modulated light having a specific wavelength of 840 nm and modulated light having a specific wavelength of 770 nm, for example. To do. In this case, in the case where the light emitting element 16b emits only one specific wavelength, the light source 16 is constituted by two or more light emitting elements 16b, or the light emitting unit 1 has two or more light sources. Needless to say, the present invention can be configured to have 16.

  The exit window 16c includes a transparent base material 16c1 (for example, quartz or an optically transparent transparent resin) that optically transmits modulated light having a specific wavelength by the light emitting element 16b, and a transparent base material 16c1. The transparent conductive film 16c2 is formed on at least one side. Here, the material for forming the transparent conductive film 16c2 is preferably selected from ITO (Indium Tin Oxide), ZnO (Zinc Oxide), or NbO (Niobium Oxide). And the transparent conductive film 16c2 can be formed with respect to the transparent base material 16c1, for example using a well-known vapor deposition method etc., As the formation film thickness, it is about 100 nm, for example. In this way, instead of forming the emission window 16c from the transparent base material 16c1 and the transparent conductive film 16c2, for example, it is also possible to thin the bulk material of ITO, ZnO, and NbO to form the emission window 16c. It is. Further, the transparent conductive film 16c2 is at least used for the thin film conductive layer 16a3 of the case 16a by using a metal sealant such as a conductive adhesive (for example, silver paste) or solder, or an internal buffer (not shown). It is electrically connected by the pressure of the material.

  As shown in FIG. 4, the light detection unit 2 detects extremely weak modulated light that propagates while reflecting inside the living body, and an electrical biological information signal related to biological information that the detected modulated light has. Is output. For this reason, the light detection unit 2 includes a light receiver 21 that receives the modulated light emitted from the light emission unit 1 and propagated through the living body. As shown in FIG. 5, the light receiver 21 includes a photoelectric conversion element 21b housed in a case 21a, and an incident window 21c that transmits the modulated light propagated through the living body to the photoelectric conversion element 21b. Yes.

  Similarly to the case 16a of the light emitting portion 1, the case 21a is also formed of a non-conductive material having excellent insulating properties, for example, a resin material such as ABS, and is formed from a cylindrical case main body 21a1 and a case cap 21a2. It is configured. The case body 21a1 houses the photoelectric conversion element 21b, and the case cap 21a2 seals the housed photoelectric conversion element 21b in the case body 21a1 by, for example, screwing. Further, the inner peripheral side of the case main body 21a1 and the case cap 21a2 and the contact portion (screwed portion) between the case main body 21a1 and the case cap 21a2 are made of a metal material having excellent conductivity by, for example, electroless plating. A thin film conductive layer 21a3 is formed. Here, the thin-film conductive layer 21a3 includes, for example, a strike-plated nickel (Ni) layer, and a copper (Cu) layer or gold (Au) having a thickness of about 10 μm electrolessly plated on the nickel (Ni) layer. It is good to form from a layer. The thin film conductive layer 21a3 is also grounded via an electrode (not shown).

  The photoelectric conversion element 21b is, for example, a PIN photodiode or an avalanche photodiode whose main component is a semiconductor such as Si (silicon) or InGaAs (indium gallium arsenide), and its effective detection bandwidth is set to 2f. . And the photoelectric conversion element 21b is electrically connected with respect to the amplifier 22 accommodated integrally in case main body 21a1, so that it may mention later.

  The incident window 21c includes a transparent substrate 21c1 (for example, quartz or optically transparent transparent resin) that optically transmits modulated light having a specific wavelength with respect to the photoelectric conversion element 21b, and a transparent substrate. The transparent conductive film 21c2 formed on at least one surface side of the material 21c1. The transparent conductive film 21c2 is electrically connected to the thin film conductive layer 21a3 formed on the case 21a using a metal sealing material such as a conductive adhesive (for example, silver paste) or solder. Yes. Here, the material for forming the transparent conductive film 21c2 is preferably selected from ITO, ZnO, and NbO as in the thin film conductive layer 21a3 of the case 21a. Further, regarding the formation of the transparent conductive film 21c2, similarly to the transparent conductive film 16c2, it can be formed by using, for example, a well-known vapor deposition method, and the formed film thickness is, for example, about 100 nm. . Note that the film thickness of the transparent conductive film 21c2 is not limited to this, and a larger film thickness (for example, about 500 nm) can be formed. Further, the transparent conductive film 21c2 can also form the entrance window 21c by thinning a bulk material of ITO, ZnO, and NbO.

  In this embodiment, a PIN photodiode or an avalanche photodiode is used as the photoelectric conversion element 21b. For example, two-dimensional optical information is acquired using a photoelectric conversion element such as a CCD or a CMOS. Is also possible. In this case, a transparent insulating layer corresponding to the transparent substrate 21c1 is formed on the surface of a CCD or CMOS, and a transparent conductive film 21c2 is formed through the insulating layer, and the transparent conductive film 21c2 is grounded. It is preferable to be electrically connected to the thin film conductive layer 21a3.

  As shown in FIG. 5, the amplifier 22 is housed in a case 21a (case body 21a1) of the light receiver 21, and an electrical detection signal output from the light receiver 21 (more specifically, the photoelectric conversion element 21b). This is an amplifier circuit (low noise amplifier) that amplifies the intensity of (analog signal). Therefore, as shown in FIG. 6, the amplifier 22 includes an operational amplifier 22a and a signal output terminal 22b that outputs an amplified electrical detection signal (analog signal). In addition, although detailed illustration is abbreviate | omitted around the signal output terminal 22b, the electrical short circuit is prevented by the insulating glass, nonelectroconductive resin, etc. The signal output terminal 22b is connected to, for example, a coaxial cable. The outer peripheral metal layer of the coaxial cable is electrically connected to a thin film conductive layer 21a3 formed in the case 21a of the light receiver 21. It has come to be.

  The operational amplifier 22a has characteristics that the input impedance is extremely high (for example, about 40 MΩ) and the output impedance is low (for example, about 150Ω), and is connected to the positive power supply terminal 22a1 and the negative power supply terminal 22a2. By the way, since the photoelectric conversion element 21b of the light receiver 21 is zero or reverse biased when detecting the modulated light, its output impedance becomes a large value close to mega ohms. In such a high output impedance state, a weak electromagnetic wave, that is, a current induced by a noise electric field (noise) generates a large noise voltage. Therefore, an electrical detection signal (analog signal) does not pass through the amplifier 22. ), The S / N ratio of the output electrical detection signal (analog signal) is deteriorated. Therefore, if the output impedance is low, the influence of the noise electric field (noise) is reduced. Therefore, by outputting an electrical detection signal (analog signal) via the operational amplifier 22a having a low output impedance, that is, a low impedance, It is possible to output a good quality detection signal while preventing the S / N ratio from deteriorating.

  Further, by housing the amplifier 22 in the grounded case 21a of the thin film conductive layer 21a3, the effect of the external noise electric field (noise) on the electrical detection signal (analog signal) output from the amplifier 22 is effectively improved. Can be blocked. This also prevents the deterioration of the S / N ratio in the electrical detection signal (analog signal) output via the amplifier 22 (more specifically, the operational amplifier 22a) and outputs a high-quality detection signal. . Thus, the electrical detection signal (analog signal) amplified by the amplifier 23 is output to the low pass filter (LPF) 23 via the signal output terminal 22b.

  The LPF 23 is, for example, a Nyquist filter that realizes an impulse response waveform that satisfies the Nyquist first criterion and prevents intersymbol interference, and has a cutoff frequency set to 2f. Accordingly, the LPF 23 removes (cuts) a signal component having a frequency higher than 2f from the detection signal (analog signal) input from the amplifier 22 and outputs the signal component to the AD converter 24.

  The AD converter 24 converts an electrical detection signal (analog signal) that has passed through the LPF 23 into a digital signal. Specifically, the AD converter 24 inputs a clock frequency 4f appropriately delayed by a delay 33 described later from the clock generator 32 of the controller 3, and converts an electrical detection signal (analog signal) into a digital signal at the sampling frequency 4f. Convert. Here, when the AD converter 24 performs digital conversion processing at a sampling frequency 4f that is twice the effective detection bandwidth 2f of the light receiver 21, a generally known sampling theorem (sampling theorem or Nyquist theorem) is obtained. Is said).

  That is, according to the sampling theorem, in order to accurately reproduce the target signal, it is necessary to sample using a sampling frequency that is at least twice the frequency of the target signal. Here, the “target signal” in the sampling theorem is an “electric detection signal (analog signal) output from the amplifier 22 corresponding to the intensity of the modulated light propagated in the living body received by the light receiver 21. It is. In addition, since the “frequency of the target signal” in the sampling theorem is 2f that matches the effective detection bandwidth of the light receiver 21 (or the cutoff frequency of the LPF 23), by setting the sampling frequency to 4f, AD The sampling theorem is established in the digital conversion processing by the converter 24. In other words, the information (that is, the analog detection signal) included in the modulated light that matches the effective detection bandwidth 2f of the light receiver 21 (or the cut-off frequency of the LPF 23) can be accurately digitalized without causing information loss or the like. Converted to a signal.

  Thus, when the AD converter 24 converts the electrical detection signal (analog signal) to a digital signal at the sampling frequency 4 f, the AD converter 24 outputs the converted digital signal to the first multiplier 25. The first multiplier 25 receives the converted digital signal and also receives the clock frequency 2 f supplied with a delay from the clock generator 32 of the controller 3 via the delay 33. The first multiplier 25 demodulates the digital signal using the clock frequency 2 f input from the clock generator 32. In the following description, the signal demodulated by the first multiplier 25 is referred to as a primary demodulated signal. When the digital signal is demodulated in this way, the first multiplier 25 outputs the primary demodulated signal to the second multiplier 26.

  The second multiplier 26 compares the primary demodulated signal input from the first multiplier 25 and the PN sequence supplied with delay from the spread code sequence generator 11 of the light emitting unit 1 via the delay 33 of the controller 3. Take the product. As described above, by acquiring the PN sequence, the second multiplier 26 modulates the light emitted from the light source 16 of the specific light emitting unit 1 among the plurality of light emitting units 1 as will be described in detail later. The primary demodulated signal corresponding to the light can be demodulated by despreading the spectrum. Then, the second multiplier 26 outputs an electrical detection signal (digital signal) demodulated by spectrum despreading, that is, a secondary demodulated signal, to the accumulator 27.

  The accumulator 27 adds the PN sequence generated by the spread code sequence generator 11 of the light emitting unit 1 over one period to the supplied secondary demodulated signal. The accumulator 27 is a very weak modulated light emitted from the specific light emitting unit 1 (more specifically, the light source 16 of the specific light emitting unit 1) and attenuated in the living body, in other words, A biological information signal corresponding to the intensity of the modulated light including biological information is output to the controller 3. Here, as shown in FIG. 4, there are a plurality of second multipliers 26 and accumulators 27 according to the number of specific wavelengths emitted from the light emitting unit 1 (one light emitting unit 1 in this embodiment). If there are a plurality of light emitting sections 1 that can receive light, the number obtained by multiplying the number of each existing light emitting section 1) is provided. Thereby, a biological information signal corresponding to the intensity of each modulated light propagated in the living body can be obtained simultaneously.

  As shown in FIG. 7, the controller 3 includes a control unit 31 having a microcomputer composed of a CPU, a ROM, a RAM, a timer and the like as main components. The controller 3 is provided with a clock generator 32 and a delay 33 in order to control the operation of the light emitting unit 1 and the light detecting unit 2 as described above. As described above, the clock generator 32 matches the effective detection bandwidth of the light receiving unit 21 constituting the photodetecting unit 2 and is a clock frequency as a second frequency that is twice the frequency f as the first frequency. 2f and a clock frequency 4f that is twice the clock frequency 2f are supplied to the light emitting unit 1 and the light detecting unit 2. The delay 33 is generated by each spreading code sequence generator 11 of each light emitting unit 1 to be described later and supplied to the light detection unit 2 and the clock frequency 4f or clock frequency supplied from the clock generator 32 to the light detection unit 2 2f is delayed appropriately. Here, in this case, since the delay characteristic may be different for each path of light propagating from the light emitting unit 1 toward the light detecting unit 2, the delay 33 is provided for each light detecting unit 2. Thus, the biological information can be obtained more accurately.

  Furthermore, the controller 3 outputs data representing the calculated biological information to the display unit 4. The display unit 4 is composed of, for example, a liquid crystal display or the like, and displays biological information in a predetermined manner based on data supplied from the controller 3.

  As schematically shown in FIG. 8, the holder 5 includes a pallet member 51, a belt member 52, a connecting member 53, and a guide member 54. As shown in FIG. 8, the pallet member 51 is formed of a hard and thin resin material (for example, ABS resin), and has a plurality of experimentally measured curved shapes of human heads. A three-dimensional curved surface is formed in accordance with the curved surface shape (curvature) of the head obtained by averaging (curving) the (curvature). The pallet member 51 is formed with a plurality of through holes 51a for holding the light emitting portion 1 and the light detecting portion 2 described above. Furthermore, the pallet member 51 is formed with an adjustment portion 51b composed of a plurality of small-diameter through holes that enables fine adjustment of the connection position with the connection member 53 when mounted on the head T of the subject. . Here, the pallet member 51 is formed, for example, for the frontal region, for the temporal region, for the occipital region, for the top of the head, or for the side of the head from the top. Thereby, when measuring biological information using the biological information measuring device S, the forehead, the temporal region, the occipital region, and the top of the head are adjusted according to the measurement region of the head for measuring the biological information. Alternatively, the pallet member 51 for the temporal region to the temporal region can be selectively used alone or in combination.

  The belt member 52 is fixed circumferentially with respect to the subject's head T and, more specifically, the pallet member 51 is attached to the head T as shown schematically in FIG. To do. For this reason, the belt member 52 is formed in a string shape from a resin material having flexibility, and is arranged in a circumferential shape corresponding to the head T, more specifically, the frontal bone in the skull forming the head T. A curved line that connects the first portion 52a, the second portion 52b arranged circumferentially corresponding to the occipital bone in the skull, and the first portion 52a and the second portion 52b to bypass the ear of the subject. And a connecting portion 52c arranged corresponding to the temporal bone in the skull. And the 2nd part 52b formed in the both ends of the string-like belt member 52 is connected by the circumference adjustment mechanism 52d. As schematically shown in FIG. 9, the circumferential length adjusting mechanism 52d includes a long hole-shaped slide portion 52c1 formed in one (one end side) second portion 52c and the other (other end side) second portion 52c. An adjustment dial 52d1 is provided that slides in the opposite direction relatively to each other in a state where the long hole-like slide portions 52c1 formed on the two are overlapped with each other. As a result, the belt member 52 is placed on the head T of the subject, the adjustment dial 52d1 of the circumference adjustment mechanism 52d is rotated, and the slide portion 52c1 is slid in the opposite direction relative to each other. The length can be arbitrarily changed according to the circumference of the head T of the subject, and the belt member 52 can be firmly fixed to the head T of the subject.

  In the present embodiment, as schematically shown in FIG. 8, the first member 52a, the second member 52b, and the connecting member 52c of the belt member 52 are integrated into a string shape. However, the first portion 52a, the second portion 52b, and the connection portion 52c can be divided individually and connected using, for example, a connecting material such as a buckle. In this case, according to the measurement area, for example, as shown in FIG. 10, the first portion 52a is omitted to measure the forehead, and the forehead pallet member 51 and the connection portion 52c are used. It is possible to directly connect and carry out, or omit the second portion 52b to measure the occipital region and directly connect the pallet member 51 for the occipital region and the connecting portion 52c. Become. In the present embodiment, a circumference adjusting mechanism 52d having an adjustment dial 52d1 is provided to adjust the circumference of the belt member 52, and the circumference within a range in which the slide portions 52c1 of the second portion 52b can slide with each other is provided. The length is adjusted as possible. In this case, for example, a belt member 52 that matches the circumference of the average child's head, a belt member 52 that matches the circumference of the average adult woman's head, and the head of the average adult man. A belt member 52 is prepared in accordance with the circumferential length. Further, for example, a rubber band or the like molded from an elastic material is hooked on both ends of the second portion 52b, that is, the belt member 52 so as to absorb the difference in the circumference of the head due to individual differences. Is possible.

  The connecting member 53 is formed in a stretchable string shape, and connects the pallet member 51 and the belt member 52. Thereby, the connection member 53 can adjust the distance between the pallet member 51 and the belt member 52. Here, depending on the measurement region (for example, the frontal head or the back of the head), instead of the connecting member 53 connecting the pallet member 51 and the belt member 52, for example, as shown in FIG. It is also possible to connect the connection portions 52c through the top of the subject's head. In this case, for example, by increasing the length of the connecting member 53, the belt member 52 can be lowered with respect to the head T of the subject, and conversely, the length of the connecting member 53 is shortened. Thus, the belt member 52 can be raised upward with respect to the head T of the subject.

  As schematically shown in FIG. 11, the guide member 54 is assembled in a through hole 51 a formed in the pallet member 51, and an appropriate state (in the head T) determined in advance with respect to the head T of the subject. For fixing the light source 16 of the light emitting unit 1 and the light receiving unit 21 of the light detecting unit 2 to the pallet member 51 by the latch mechanism 6 according to a predetermined arrangement direction toward the reference point, a contact state with the scalp, etc. It is. For this reason, the guide member 54 is inserted into the case 16a of the light source 16 and the case 21a of the light receiving unit 21, and is a guide member main body 54a that comes into contact with a spring 61 of the latch mechanism 6 described later, and a screw formed on the guide member main body 54a. A guide member nut 54b for fixing the guide member main body 54a to the pallet member 51 by being screwed to the portion.

  The latch mechanism 6 is for freely attaching and detaching the light source 16 of the light emitting unit 1 and the light receiver 21 of the light detecting unit 2 to the holder 5. Therefore, the latch mechanism 6 includes a latch ring 61 and a coil spring 62 as ring members as shown in FIG. The latch ring 61 is formed in an annular shape through which a case 16a of the light source 16 and a case 21a of the light receiver 21 can be inserted from a resin material (for example, ABS resin). The latch ring 61 has a plurality of engaging protrusions 16a4 and 21a4 (FIGS. 3 and 5) formed on the outer peripheral surfaces of the case bodies 16a1 and 21a1 of the cases 16a and 21a with a predetermined interval in the circumferential direction. 5), groove portions 61a are formed on the inner peripheral surface side to allow the engaging protrusions 16a4 and 21a4 to be inserted in the axial direction. In addition, the latch ring 61 is formed with an engaging portion 61 b that is integrally engaged with one end side of the coil spring 62. As shown in FIG. 13, the coil spring 62 is disposed between the latch ring 61 and the guide member 54 of the holder 5 (more specifically, the lower surface of the guide member main body 54a of the guide member 54). When the pallet member 51 of the holder 5 is attached to T, the light source 16 and the light receiver 21 inserted through the guide member 54 are urged toward the scalp of the head.

  Next, the operation of the biological information measuring device S configured as described above will be described. In the following description, the case of observing a change in blood flow in the head T of the subject, more specifically, in the brain will be described as an example.

  Blood flowing through arteries and veins of a living body (hereinafter referred to as arterial blood and venous blood, respectively) does not bind hemoglobin combined with oxygen (hereinafter, this hemoglobin is referred to as oxygenated hemoglobin) and oxygen. Hemoglobin (hereinafter, this hemoglobin is referred to as reduced hemoglobin). The amount of oxygenated hemoglobin and the amount of reduced hemoglobin in arterial blood and venous blood change depending on the activity of the living body. Here, by calculating the difference in the degree of absorption of near-infrared light by oxygenated hemoglobin and reduced hemoglobin, it is possible to observe a change accompanying a biological activity, that is, a change in blood flow. Therefore, the controller 3 of the biological information measuring device S uses the biological information signal corresponding to the intensity of the modulated light propagated in the subject's brain, as will be described later, oxygenation in arterial blood and venous blood in the brain. The hemoglobin concentration length change ΔCoxy and the reduced hemoglobin concentration length change ΔCdeoxy are calculated as biological information.

  For this reason, when operating biological information measuring device S in this embodiment, as shown in Drawing 8, as a measurement field in a subject's head T, for example, from the top of the head to the temporal periphery position The pallet member 51 of the holder 5 to which the light sources 16 of the plurality of light emitting units 1 and the light receivers 21 of the plurality of light detection units 2 are assembled is fixedly mounted. Hereinafter, the mounting of the holder 5 will be described.

  For example, an operator who operates the biological information measuring device S first assembles the light source 16 of the light emitting unit 1 and the light receiver 21 of the light detecting unit 2 to the pallet member 51 of the holder 5 as shown in FIG. Specifically, the operator inserts the light source 16 or the light receiver 21 from the guide member nut 54 b side of the guide member 54 with an arbitrary arrangement with respect to the guide member 54 fixed in advance in the through hole 51 a of the pallet member 51. To do. At this time, the large-diameter portion of the case main body 16a1 constituting the case 16a of the light source 16 (matches the outer diameter of the case cap 16a2) and the large-diameter portion of the case main body 21a1 constituting the case 21a of the light receiver 21 (of the case cap 21a2). The outer diameter is equal to the inner diameter of the guide member 54, so that the light source 16 and the light receiver 21 are not inserted through the guide member 54 of the pallet member 51.

  Subsequently, the operator attaches the latch mechanism 6 in which the latch ring 61 and the coil spring 62 are integrated to the light source 16 and the light receiver 21 through which the guide member 54 is inserted, and the light source 16 and the light receiver 21 are attached to the pallet member 51. Assemble. At this time, the operator aligns the groove 61a formed on the latch ring 61 with the engagement protrusions 16a4 and 21a4 formed on the case main body 16a1 of the light source 16 and the case main body 21a1 of the light receiver 21, and sets the coil spring 62 at the head. The case 16a and the case 21a are pushed in the axial direction. Then, the operator rotates the latch ring 61 at a position where the engagement protrusions 16a4 and 21a4 have passed relative to the groove 61a of the latch ring 61, and the lower surface side of the latch ring 61 and the engagement protrusion 16a4. The upper surface side of 21a4 is engaged. As a result, the latch mechanism 6 assembles the light source 16 and the light receiver 21 with respect to the pallet member 51 of the holder 5 while allowing the coil spring 62 to be slightly compressed.

  Here, as described above, the light source 16 of the light emitting unit 1 and the light receiver 21 of the light detecting unit 2 are extremely easy with respect to the guide member 54 attached in advance to the pallet member 51 of the holder 5 by the latch mechanism 6. And can be fixed quickly. Therefore, the light source 16 and the light receiver 21 can be freely attached to and detached from the pallet member 51 in accordance with the measurement purpose. For example, various arrangements such as a matrix shape or a donut shape are extremely easy. Can be realized. Further, as will be described later, the light receiver 21 of the light detection unit 2 can reliably identify a specific (arbitrary) light emission unit 1 from the light sources 16 of the plurality of light emission units 1. For this reason, the light source 16 of the light emitting unit 1 and the light receiver 21 of the light detecting unit 2 are close to (adjacent to) the guide member 54 attached in advance to the pallet member 51 of the holder 5. Biological information can be measured by arranging or fixing the light source 16 and the light receiver 21 so as to be separated from each other. This makes it possible to measure biological information at different depths in the subject brain.

  Next, as shown in FIG. 8, the operator moves the pallet member 51 in which the light sources 16 of the plurality of light emitting units 1 and the light receivers 21 of the plurality of light detecting units 2 are assembled from the top of the subject to the vicinity of the temporal region. The first portion 52a of the belt member 52 is disposed so as to correspond to the frontal bone so that the connection portion 52c of the belt member 52 bypasses the subject's ear, and the second portion 52b of the belt member 52 is rearward. Place it according to the skull. Then, the adjustment dial 52d1 of the peripheral length adjustment mechanism 52d provided in the second portion 52b of the belt member 52 is rotated to adjust the peripheral length of the belt member 52, and the belt member with respect to the predetermined position of the head T of the subject. 52 is fixed. In addition, the length of the connecting member 53 that connects the pallet member 51 and the belt member 52 in a state where the pallet member 51 is applied from the top of the subject to the vicinity of the temporal region, as schematically shown in FIG. A state in which the light source 16 of the light emitting unit 1 and the light receiver 21 of the light detecting unit 2 attached to the pallet member 51 are pushed back, more specifically, the coil spring 62 of the latch mechanism 6 is compressed by a predetermined amount to guide the light. Maintaining a state in which a predetermined gap is generated between the upper surface of the guide member nut 54b of the member 54 and the lower surface of the large diameter portion of the case main body 16a1, 21a1, a predetermined distance is provided between the lower surface of the pallet member 51 and the scalp. Adjust so that Thereby, the light source 16 of the light emission part 1 and the light receiver 21 of the light detection part 2 fixed integrally to the holder 5, in other words, the pallet member 51, are firmly attached to the subject's head T in a circumferential shape. Using the fixed belt member 52, the belt member 52 can be fixed to an accurate measurement position very easily and quickly.

  Thus, when the holder 5 is fixed to the measurement position on the head T of the subject, the operator operates the biological information measurement device S by operating an input device (not shown). More specifically, the control unit 31 of the controller 3 operates the light emission units a to f and the light detection units A to F as schematically shown in FIG.

  First, light emission by the light emission portions a to f will be described. When the operation of the biological information measuring device S is started, the control unit 31 of the controller 3 generates (emits) modulated light having specific wavelengths of 840 nm and 770 nm, for example, to the light emitting units a to f. For this purpose, the baseband output device 13 is activated. Thereby, each light source 16 of the light emitting parts a to f starts to emit modulated light having specific wavelengths of 840 nm and 770 nm, respectively.

  That is, in the light emitting units a to f, each spreading code sequence generator 11 generates a gold code sequence as a PN sequence, for example. The spreading code sequence generator 11 outputs the generated PN sequence to the control unit 31 of the controller 3 and also outputs it to the first multiplier 12. As a result, the first multiplier 12 takes the product of the DC signal (baseband signal) supplied from the baseband output unit 13 and the PN sequence, and performs spread spectrum modulation on the DC signal.

  Subsequently, the spread spectrum modulated primary modulation signal is output to the second multiplier 14. Then, the second multiplier 14 supplies a secondary modulation signal obtained by further modulating the primary modulation signal using the clock frequency 2f supplied from the clock generator 32 to the light source driver 15, whereby each of the light emitting units a to f. Each of the light sources 16 emits modulated light having a specific wavelength.

  Here, as described above, in the light source 16, the light emitting element 16b is accommodated in the case 16a (case body 16a1) having the grounded thin film conductive layer 16c3, and the thin film conductive of the case 16a (case body 16a1). The modulated light is emitted through the emission window 16c electrically connected to the layer 16a3. Thereby, electromagnetic waves generated when the light emitting element 16b performs a light emission operation, that is, a noise electric field (noise) is prevented from leaking to the outside due to the conductivity of the case 16a (more specifically, the thin film conductive layer 16a3). The transparent conductive film 16c2 of the exit window 16c is electrically connected to the thin film conductive layer 16a3, thereby preventing leakage to the outside. That is, although the light source 16 of each light emission part a-f emits the modulated light which has a specific wavelength, it effectively prevents that the noise electric field (noise) generated with light emission operation leaks outside. be able to. Thereby, it is possible to prevent the generated noise electric field (noise) from propagating to the light detection units A to F through the living body (human body), for example, and adversely affecting the detection of the reflected light by the light receiver 21. . Therefore, the detection accuracy of the modulated light by the light detection units A to F can be dramatically improved, and as a result, the measurement accuracy of biological information can be greatly improved.

  Further, as described above, the light source 16 is assembled to the pallet member 51 of the holder 5 that is firmly fixed to the head T corresponding to the measurement position. Further, as shown in FIG. 13, in the light source 16, the emission window 16 c is pressed against the scalp of the head T of the subject by the urging force of the coil spring 62 of the latch mechanism 6. Thereby, the modulated light emitted from the light emitting element 16b through the emission window 16c is emitted directly to the scalp without being affected by, for example, the hair. Therefore, the light emitting portions a to f can efficiently emit modulated light toward the head T of the subject, more specifically, the brain in the skull, and as a result, the measurement accuracy of biological information is greatly increased. Can be improved.

  In this way, the modulated light emitted from the light sources 16 of the light emitting parts a to f passes through the skull of the head T, which is the subject, so that each part of the surface of the brain, for example, the pallet member 51 is the head. When it is fixed from the parietal part to the temporal region of the part T, it enters the parietal lobe and the temporal lobe and propagates while diffusely reflecting in the brain, in other words, attenuated. In the following description, modulated light that propagates while being attenuated by irregular reflection is referred to as reflected light. Then, the two modulated lights emitted from the light sources 16 of the light emitting portions a to f, that is, the reflected light, pass through the skull of the head T again and reach the outer surface (scalp) of the head T.

  Next, detection of reflected light by the light detection units A to F will be described. Each reflected light that has arrived at the scalp of the head T is detected by the light detection units A to F. That is, in the light detection units A to F, each of the light receivers 21 receives all of the reflected light reaching the scalp, and an electrical detection signal (analog signal) is amplified in time series according to the received reflected light. 22 to output. The amplifier 22 amplifies the input electrical detection signal, and the LPF 23 cuts a signal component having a frequency higher than 2f by passing the amplified detection signal.

  Here, as described above, in the light receiver 21, the photoelectric conversion element 21b is accommodated in the case body 21a1 in which the grounded thin film conductive layer 21a3 is formed, and the reflected light is electrically connected to the thin film conductive layer 21a3. Is incident through the incident window 21c connected to the. Thereby, for example, a noise electric field (noise) due to a myoelectric potential generated with the movement of the subject and a noise electric field (noise) existing in the external environment of the light detection units A to F are generated in the case 21a (more specifically, in the case main body 21a1. Propagation to the inside is blocked by the conductivity of the formed thin film conductive layer 21a3), and the propagation to the inside is blocked by the transparent conductive film 21c2 of the entrance window 21c being electrically connected to the thin film conductive layer 21a3. Is done. Further, since the amplifier 22 is also accommodated in the case 21a of the light receiver 21, the external noise electric field (noise) propagating to the amplifier 22 is also cut off.

  The electrical detection signal (analog signal) output from the light receiver 21 is amplified by the low impedance amplifier 22 and output via the signal output terminal 22b. It is possible to prevent an external noise electric field (noise) from being applied (ridden) to (analog signal). Furthermore, since a coaxial cable is connected to the signal output terminal 22b of the amplifier 22, noise existing outside is detected with respect to an electrical detection signal (analog signal) output to the LPF 23 via the signal output terminal 22b. It is also possible to prevent an electric field (noise) from being applied (ride). Therefore, the detection accuracy of the reflected light by the light detection units A to F can be dramatically improved, and as a result, the measurement accuracy of biological information can be greatly improved.

  Further, as described above, the light receiver 21 is assembled to the pallet member 51 of the holder 5 that is firmly fixed to the head T corresponding to the measurement position. Further, as shown in FIG. 13, in the light receiver 21, the incident window 21 c is pressed against the scalp of the head T, which is the subject, by the urging force of the coil spring 62 of the latch mechanism 6. Thereby, the weak reflected light received by the photoelectric conversion element 21b through the incident window 21c is received directly from the scalp without being affected by, for example, the hair. Therefore, the light detection units A to F can efficiently receive the reflected light that has propagated through the head T that is the subject, more specifically, the brain within the skull, and as a result, the measurement accuracy of biological information can be improved. It can be greatly improved.

  Subsequently, the AD converter 24 digitally converts the electrical detection signal (analog signal) that has passed through the LPF 23 at the sampling frequency 4f. The digital detection-processed electrical detection signal (digital signal) is output to the first multiplier 25, and the first multiplier 25 converts the input electrical detection signal (digital signal) to the clock frequency 2f. The demodulated detection signal, that is, the primary demodulated signal is output to the second multiplier 26. By demodulating in this way, the primary demodulated signal becomes a signal using the entire effective detection bandwidth 2f of the light receiver 21. In other words, information of the reflected light (modulated light) that can be received by the light receiver 21 is lost, for example, the attenuation state of the modulated light (that is, the light intensity of the reflected light) propagated around the parietal lobe and temporal lobe. Therefore, the primary demodulated signal accurately converted into a digital signal can be output to the second multiplier 26.

  By the way, each modulated light emitted from each light source 16 of the light emitting parts a to f reaches each light detecting part A to F as reflected light. For example, as shown in FIG. 14, the light detection unit A assembled to the pallet member 51 of the holder 5 includes the modulated light emitted from the light emitting units a, b, c, and d assembled around the light detection unit A. In addition, the modulated light emitted from the light emitting portions e and f also reaches the reflected light. In such a situation, the control unit 31 of the controller 3 corresponds to, for example, the reflected light of the modulated light emitted from the light emitting units a, b, c, and d among the reflected light reaching the light detection unit A. The light detection unit A is controlled so that only the biological information signal to be obtained is obtained. The control by this control part 31 is demonstrated concretely.

  As described above, the control unit 31 of the controller 3 acquires the PN sequence from the spread code sequence generator 11 of each of the light emitting units a to f. On the other hand, the second multiplier 26 of the light detection unit A acquires the PN sequence generated by the spread code sequence generator 11 of the light emitting units a to f via the control unit 31 of the controller 3. At this time, the control unit 31 transmits the different PN sequences generated by the spread code sequence generators 11 of the light emitting units a, b, c, and d via the delay 33 to the second multiplier corresponding to the light detection unit A. 26.

  Thus, each second multiplier 26 takes the product of the primary demodulated signal output from the first multiplier 25 and the PN sequence supplied from the control unit 31 of the controller 3, in other words, spectrum despreading, The obtained secondary demodulated signal is output to each accumulator 27. Each accumulator 27 adds the output secondary demodulated signal over one period or more of the PN sequence. As described above, the product-sum processing by the second multiplier 26 and the accumulator 27 corresponding to the emitted modulated light can correlate the secondary demodulated signal with the supplied PN sequence. A plurality of biological information signals corresponding to the reflected lights of the plurality of modulated lights emitted from the emission parts a, b, c, and d can be simultaneously output.

  That is, as described above, the PN sequence has the property that different sequences are orthogonal to each other, in other words, the property value of the product of different sequences is “0”. Therefore, when the control unit 31 of the controller 3 supplies, for example, a PN sequence from the corresponding spread code sequence generator 11 of the light emitting unit a to a certain second multiplier 26, the first multiplier 25, the product of the primary demodulated signal other than the primary demodulated signal corresponding to the specific modulated light emitted from the light emitting part a and the PN sequence of the light emitting part a is “ 0 ". For this reason, the secondary demodulated signal added by the accumulator 27 over one period of the PN sequence is also “0”, and the correlation is “0”.

  Therefore, the secondary demodulated signal that does not have (or does not match) the PN sequence supplied from the control unit 31 of the controller 3, in other words, the biological information signal is selectively excluded, and the specific second multiplier 26 and From the accumulator 27, only the biological information signal corresponding to the reflected light of the specific modulated light emitted from the light emitting part a is output to the control part 31 of the controller 3. Similarly, the control unit 31 of the controller 3 supplies the second multiplier 26 with, for example, a PN sequence from the spreading code sequence generator 11 corresponding to the other of the light emitting units a. The biological information signal corresponding to the reflected light of the other specific modulated light emitted from the light emitting unit a is simultaneously output from the 2 multiplier 26 and the accumulator 27 to the control unit 31 of the controller 3. Similarly, when the PN series of the other light emitting units b, c, d is supplied from the control unit 31 of the controller 3 to the second multiplier 26, the light emitting units b, c, Each biological information signal corresponding to the reflected light of the plurality of modulated lights emitted from d is simultaneously output to the controller 31 of the controller 3.

  Here, since the light detection unit A detects reflected light of the modulated light emitted by the light emission units a to d, the light detection unit A and the light emission unit a, the light detection unit A and the light emission unit b, light Four channels of the detection part A and the light emission part c and the light detection part A and the light emission part d are formed. Thereby, the light detection part A is the biological information corresponding to the reflected light of the modulated light emitted by the light emitting parts a to d among the modulated light having specific wavelengths emitted from the light emitting parts a to f. The signal is output to the control unit 31 of the controller 3. Similarly to the light detection unit A, the light detection units B to F are emitted from specific light emission units among the light emission units a to f by being controlled by the control unit 31 of the controller 3. A plurality of biological information signals corresponding to the reflected light of the modulated light are simultaneously output.

  When the biological information signals are output from the light detection units A to F in this manner, the control unit 31 of the controller 3 uses the output biological information signal to within the brain of the head T (for example, the parietal lobe and the side). The oxygenated hemoglobin concentration length change ΔCoxy and the reduced hemoglobin concentration length change ΔCdeoxy in the vicinity of the head lobe are calculated. The calculation of oxygenated hemoglobin concentration length change ΔCoxy and reduced hemoglobin concentration length change ΔCdeoxy will be specifically described below, but the calculation method itself is not a feature of the present invention. That is, the oxygenated hemoglobin concentration length change ΔCoxy and the reduced hemoglobin concentration length change ΔCdeoxy are exemplarily shown as biological information that can be measured by the biological information measuring device S. For this reason, various conventionally known methods can be used for calculating oxygenated hemoglobin concentration length change ΔCoxy and reduced hemoglobin concentration length change ΔCdeoxy, and the following description is intended to limit the calculation method. is not.

As described above, oxygenated hemoglobin and reduced hemoglobin in arterial blood and venous blood absorb near infrared light due to different light absorption characteristics. The absorption characteristics of near-infrared light in oxygenated hemoglobin and reduced hemoglobin can be generally expressed by the following formula 1 according to the Lambert-Beer law.
-Log10 (R (λ) / Ro (λ)) = εoxy (λ) × Coxy × d + εdeoxy (λ) × Cdeoxy × d + α (λ) + S (λ) Equation 1

  However, R (λ), Ro (λ), and d in the equation 1 respectively represent the detected light amount of the wavelength λ, the emitted light amount of the wavelength λ, and the optical path length of the detection region, as schematically shown in FIG. It represents. In the above formula 1, εoxy (λ) represents the molecular extinction coefficient of oxygenated hemoglobin with respect to the wavelength λ, and εdeoxy (λ) represents the molecular extinction coefficient of reduced hemoglobin with respect to the wavelength λ. Further, Coxy in the above formula 1 represents the concentration of oxygenated hemoglobin, and Cdeoxy represents the concentration of reduced hemoglobin. Furthermore, α (λ) in the above formula 1 represents the attenuation due to light absorption of a dye other than hemoglobin in blood (for example, cytochrome aa33 reflecting the supply and demand of oxygen in mitochondria in cells). (λ) represents the attenuation due to light scattering of the living tissue.

  Thus, according to Equation 1, the oxygenated hemoglobin concentration Coxy and the reduced hemoglobin concentration Cdeoxy in the case of using near infrared light having a wavelength of 840 nm and near infrared light having a wavelength of 770 nm are calculated. Can do. Therefore, the blood flow change can be calculated by calculating the ratio Coxy / Cdeoxy between the oxygenated hemoglobin concentration Coxy and the reduced hemoglobin concentration Cdeoxy.

For example, if the light absorption characteristic before blood flow change is expressed according to the above-mentioned formula 1 for the capillary blood vessels existing in the brain, the light absorption characteristic after blood flow change can be expressed as the following formula 2.
−log10 (growthR (λ) / Ro (λ)) = εoxy (λ) × growthCoxy × d + εdeoxy (λ) × growthCdeoxy × d + growthα (λ) + S (λ) Equation 2
However, growthR (λ), growthCoxy, growthCdeoxy, and growthα (λ) in Equation 2 above represent values that have increased or decreased due to blood flow changes accompanying heartbeat, respectively. It represents the detected light amount, the oxygenated hemoglobin concentration after blood flow change, the reduced hemoglobin concentration after blood flow change, and the attenuation due to light absorption of pigments other than hemoglobin after blood flow change.

Here, since the light absorption amount of hemoglobin in the blood is extremely larger than the light absorption amount of a dye other than hemoglobin, α (λ) in the above equation 1 is expressed as α (λ) = growthα (λ). be able to. Thus, subtracting the formula 1 from the formula 2 yields the following formula 3.
-Log10 (growthR (λ) / R (λ)) = εoxy (λ) × ΔCoxy + εdeoxy (λ) × ΔCdeoxy Equation 3
Here, ΔCoxy and ΔCdeoxy in the formula 3 are represented by the following formula 4 and formula 5, respectively.
ΔCoxy = (growthCoxy−Coxy) × d Equation 4
ΔCdeoxy = (growthCdeoxy−Cdeoxy) × d (Formula 5)

  Then, as schematically shown in FIG. 16, the light absorption spectrum of hemoglobin is based on the result of measurement using near infrared light of λ = 770 nm or 840 nm as a specific wavelength that makes the contrast ratio of the light absorption characteristic clear. By solving Equation 3, it is possible to relatively calculate oxygenated hemoglobin concentration length change ΔCoxy and reduced hemoglobin concentration length change ΔCdeoxy including the optical path length, or total hemoglobin concentration length change (ΔCoxy + ΔCdeoxy) as dimensions.

  Then, the controller 31 of the controller 3 calculates the oxygenated hemoglobin concentration length change ΔCoxy and the reduced hemoglobin concentration length change ΔCdeoxy, that is, biological information, and outputs the calculated biological information to the display unit 4. The display unit 4 displays the blood flow change in the brain based on the biological information calculated and output by the control unit 31.

  In this case, as described above, in the biological information measuring apparatus S, the light emitting unit 1 identifies which reflected light received by the light detection unit 2 uses the PN series is based on the modulated light. Therefore, a plurality of light sources 16 of the light emitting unit 1 and light receivers 21 of the light detecting unit 2 can be assembled to the pallet member 51 of the holder 5 in an arbitrary arrangement. In other words, in the biological information measuring device S, the light sources 16 of the plurality of light emitting units 1 may be closely arranged and assembled around the light receiver 21 of the photodetecting unit 2 assembled to the pallet member 51 of the holder 5. Without causing crosstalk, the light detection unit 2 can selectively detect only the reflected light of the modulated light emitted from the specific light emission unit 1. Therefore, if each of the plurality of light detection units 2 selectively detects only the reflected light of the modulated light emitted from the specific light emission unit 1, as shown in FIG. The portion where the modulated light emitted to the surface is reflected by the brain surface layer becomes dense, in other words, the measurement resolution can be increased and the measurement target range can be captured in a planar shape. Thereby, based on the biological information in the measurement region captured by the display unit 4 in a planar shape, for example, by displaying blood flow changes two-dimensionally, changes in blood flow accompanying brain activity are observed in detail. can do.

  Further, in the biological information measuring apparatus S, the light source 16 of the light emitting unit 1 and the light receiver 21 of the light detecting unit 2 are easily and quickly attached to and detached from the pallet 5 of the holder 5 using the latch mechanism 6. be able to. Therefore, by appropriately changing the assembly position of at least one of the light source 16 of the light emitting unit 1 and the light receiver 21 of the light detecting unit 2 with respect to the pallet member 51, the depth direction is added as described above, and the brain It is also possible to observe the blood flow change accompanying the activity in three dimensions. This will be specifically described below.

  Generally, when light is emitted at a predetermined angle, the arrival position of the reflected light changes according to the distance to the reflector. That is, in a situation where light is incident from a certain emission point (exit position) at a predetermined angle, when the distance to the reflector is short, in other words, when the reflection position is shallow, the arrival position of the reflected light is the emission point. It tends to be a position close to (exit position). On the other hand, when the distance to the reflector is long, in other words, when the reflection position is deep, the arrival position of the reflected light tends to be a position far from the emission point (exit position). As described above, when the modulated light is emitted inside the head T, the modulated light is irregularly reflected inside the head T, so the exact optical path cannot be specified, but generally has the above-mentioned tendency. .

  For this reason, the operator uses the pallet member 51 of the holder 5 so that the arrangement distance between the light source 16 of the light emitting unit 1 and the light receiver 21 of the light detecting unit 2 changes during measurement using the biological information measuring device S. On the other hand, a change in blood flow in the depth direction of the brain can be measured by attaching or detaching either the light source 16 or the light receiver 21. Hereinafter, this will be specifically described with reference to FIG.

  Consider a case where the blood flow change at a shallow position on the surface of the brain, specifically, slightly on the surface side of the cerebral cortex is measured as an example. In this case, as schematically shown in FIG. 18A, the distance between the surface of the head T and the surface side of the cerebral cortex is short, in other words, from the scalp of the head T to the surface of the cerebral cortex. shallow. For this reason, for example, the operator moves the light source 16 of the light emitting unit 1 closer to the light receiver 21 of a certain light detecting unit 2, that is, the light receiving unit 21 of the light detecting unit A and the light emitting units a and c. The holder 5 is assembled to the pallet member 51 so that the distance to the light source 16 is shortened. As a result, the light receiver 21 of the light detection unit A is modulated light that is emitted from the light source 16 of the specific light emitting units a and c arranged close to each other, propagates through the surface side of the cerebral cortex, and is reflected. The reflected light is received, and a biological information signal corresponding to the intensity of the received reflected light is output to the control unit 31 of the controller 3.

  Therefore, the operator latches the light source 16 of the light emitting unit 1 and the light receiver 21 of the light detecting unit 2 so as to approach each other when measuring a blood flow change on the surface side of the brain surface layer, which is a relatively shallow measurement region. The light source 16 and the light receiver 21 can be attached to and detached from the pallet member 51 very easily and quickly using the mechanism 6. Thus, by bringing the light source 16 and the light receiver 21 closer to each other, the control unit 31 of the controller 3 changes the oxygenated hemoglobin concentration length change ΔCoxy and the reduced hemoglobin concentration length change on the surface side of the brain surface layer (at a shallow position). ΔCdeoxy, that is, biological information can be calculated.

  Next, the case where the blood flow change at a relatively deep position on the slightly inner side of the cerebral cortex is measured is considered as an example. In this case, as schematically shown in FIG. 18 (b), the distance between the surface of the head T and the back side of the cerebral cortex is long, in other words, from the scalp of the head T to the back side of the cerebral cortex. Is deep. For this reason, for example, the operator moves the light source 16 of the light emitting unit 1 away from the light receiver 21 of a certain light detecting unit 2, that is, the light receiver 16 of the light detecting unit A and the light sources 16 of the light emitting units a and c. Are assembled to the pallet member 51 of the holder 5 so that the distance between the two is longer. As a result, the light receiver 21 of the light detection unit A is modulated light that is emitted from the light sources 16 of the specific light emitting units a and c that are spaced apart from each other, propagated through the back side of the cerebral cortex, that is, reflected. The reflected light is received, and a biological information signal corresponding to the intensity of the received reflected light is output to the control unit 31 of the controller 3.

  Therefore, the operator latches the light source 16 of the light emitting unit 1 and the light receiver 21 of the light detecting unit 2 so as to be separated from each other when measuring a blood flow change on the back side of the brain surface layer, which is a relatively deep measurement region. The light source 16 and the light receiver 21 can be attached to and detached from the pallet member 51 very easily and quickly using the mechanism 6. Thus, by separating the light source 16 and the light receiver 21 from each other, the control unit 31 of the controller 3 changes the oxygenated hemoglobin concentration length change ΔCoxy and the reduced hemoglobin concentration length change on the back side (at a deep position) of the brain surface layer. ΔCdeoxy, that is, biological information can be calculated.

  Then, the control unit 31 of the controller 3 calculates the biological information on the surface side of the cerebral cortex and the back side of the cerebral cortex, that is, the oxygenated hemoglobin concentration length change ΔCoxy and the reduced hemoglobin concentration length change ΔCdeoxy in this way. Thus, the blood flow change in the depth direction in the brain can be synthesized. Accordingly, the display unit 4 can display a three-dimensional change in blood flow in the brain based on the biological information signal calculated and output by the control unit 31. Therefore, changes in blood flow accompanying brain activity can be observed in detail.

  As described above, the light detection unit 2 uses the PN sequence generated by the spread code sequence generator 11 of each light emission unit 1 to reflect the modulated light emitted from the specific light emission unit 1. Light can be selectively received and a biological information signal corresponding to the reflected light can be output to the controller 31 of the controller 3. Therefore, for example, in a situation where a change in blood flow accompanying brain activity is observed three-dimensionally, the light source 16 of the light emitting unit 1 and the light detecting unit 2 of the light emitting unit 1 are placed on the pallet member 51 of the holder 5 as shown in FIG. When the light receivers 21 are alternately arranged in a matrix and assembled, the light detection unit 2 is set to the depth of the measurement region instead of rearranging the arrangement of the light sources 16 and the light receivers 21 as described above. It is also possible to change the specific light emitting unit 1 that receives light accordingly.

  Specifically, when measuring a change in blood flow on the surface side of the cerebral cortex according to the above-described example, the control unit 31 of the controller 3 performs, for example, on the light receiver 21 of the light detection unit A illustrated in FIG. Thus, control is performed so as to receive the reflected light of the modulated light emitted by the respective light sources 16 of the light emitting portions a to d having a short distance. On the other hand, when measuring a change in blood flow slightly behind the cerebral cortex, the control unit 31 of the controller 3 is, for example, light having a long distance with respect to the light receiver 21 of the light detection unit A shown in FIG. Control is performed so as to receive the reflected light of the modulated light emitted by the light sources 16 of the emission parts e and f.

  That is, the control unit 31 acquires the PN sequence generated by each spreading code sequence generator 11 in the light emitting units a to f. And the control part 31 supplies each acquired PN series to the 2nd multiplier 26 of the photon detection part A according to the depth of a measurement area | region. Thereby, the light detection part A can selectively receive the reflected light of the modulated light emitted from the light sources 16 of the light emitting parts a to f and output a biological information signal corresponding to the reflected light. . Therefore, based on the biological information signal output in this way, the display unit 4 can display the change in blood flow in the three-dimensional brain, and the change in blood flow accompanying brain activity can be displayed in detail. Can be observed.

  As can be understood from the above description, according to the biological information measuring apparatus S of the present embodiment, a light source as an element using the holder 5 including the pallet member 51, the belt member 52, and the connecting member 53 is used. 16 and the light receiver 21 can be securely mounted at a predetermined position on the head T of the subject without causing a positional shift. Further, the light source 16 and the light receiver 21 can be attached to and detached from the pallet member 51 very easily and quickly using the latch mechanism 6 including the latch ring 61 and the coil spring 62. As a result, the light source 16 can emit near-infrared light having a specific wavelength accurately from a predetermined position into the measurement region, and the light receiver 21 has a specific wavelength that has accurately propagated in the measurement region at the predetermined position. Near infrared light can be detected.

  In this case, even if the reflected light (modulated light) is attenuated by propagating through the head T of the subject, the light receiver 21 of the light detection unit 2 is connected to the case 21a (more specifically, the case main body 21a1). In addition, since the electromagnetic shielding is performed by the thin film conductive layer 21a3) formed on the case cap 21a2 and the incident window 21c, for example, the influence of the noise electric field (noise) due to the myogenic potential generated in the living body is eliminated, and the reflected light (Modulated light) can be detected. Further, since the amplifier 22 is accommodated in the case 21a of the light receiver 21, the noise electric field (noise) propagating to the amplifier 22 is also cut off. Further, the amplifier 22 includes an operational amplifier and can output an electrical detection signal (analog signal) with low impedance. For this reason, it is possible to prevent a noise electric field (noise) existing outside from being added (ridden) to an electrical detection signal (analog signal) to be output, and to achieve good signal output performance (good S / N). Ratio) can be ensured. Thereby, the control part 31 of the controller 3 can measure (calculate) biological information very accurately.

  Furthermore, the light source 16 of the light emitting portion 1 can also be electromagnetically shielded by the case 16a (more specifically, the thin film conductive layer 16a3 formed on the case body 16a1 and the case cap 16a2) and the emission window 16c. Therefore, emission (radiation) of a noise electric field (noise) generated with the operation of the light emitting element 16b of the light source 16 can be prevented, and the influence on detection of extremely weak reflected light by the light receiver 21 of the light detection unit 2 can be prevented. Can be greatly reduced. Also by this, the control part 31 of the controller 3 can measure (calculate) biological information very accurately.

  In the above-described embodiment, the emission window 16c of the light source 16 in the light emission unit 1 and the incident window 21c of the light receiver 21 in the light detection unit 2 are formed as flat transparent base materials 16c1, 21c1, and these transparent base materials 16c1, 21c1. The transparent conductive films 16c2 and 21c2 formed on at least one side of the film were implemented. In this case, in order to emit modulated light more efficiently and improve the detection accuracy of reflected light, as shown in FIG. 19, the transparent base materials 16c1 and 21c1 are curved surfaces having a predetermined radius of curvature (for example, lenses For example, the transparent conductive films 16c2 and 21c2 may be modified to be formed on at least one side of the transparent base material 16c1 and 21c1 formed in a curved shape. Thus, when the exit window 16c of the light source 16 has a curved surface shape (for example, a lens shape), the coil spring of the latch mechanism 6 is mounted when the light source 16 is mounted on the subject's head T via the pallet member 51 of the holder 5. It is possible to emit modulated light with the exit window 16c slightly submerged with respect to the scalp of the subject by the urging force of 62, and efficiently emit the modulated light inside the head T while avoiding the hair. can do.

  Further, by making the incident window 21c of the light receiver 21 into a curved surface shape (for example, a lens shape), when the light receiving device 21 is mounted on the subject's head T via the pallet member 51 of the holder 5, the coil spring 62 of the latch mechanism 6 is used. It is possible to receive the reflected light in a state where the incident window 21c is slightly sunk with respect to the scalp of the subject by the urging force, and the reflected light can be received inside the head T while avoiding the hair. Furthermore, by allowing the reflected light to be received in a state in which the entrance window 21c having a curved surface shape (for example, a lens shape) is slightly depressed with respect to the scalp, it is possible to efficiently collect the very weak reflected light. The light intensity of the reflected light incident on the photoelectric conversion element 21b can be increased. As a result, the S / N ratio of the biological information signal corresponding to the light intensity of the reflected light can be increased, the measurement accuracy can be improved, and more accurate biological information can be obtained.

  In particular, in the incident window 21c of the light receiver 21, an optical filter 21c3 can be provided as shown in FIG. 20 in order to improve the detection accuracy of the reflected light. Here, the optical filter 21c3 has an optical characteristic that transmits only a specific wavelength of the reflected light, and has, for example, a color filter, a cut filter that removes short-wavelength light, or a different refractive index. A band-pass filter or the like in which dielectric layers are laminated can be employed.

  As described above, by providing the optical filter 21c3 in the incident window 21c of the light receiver 21, external light (for example, illumination light) existing in the measurement environment enters the photoelectric conversion element 21b through the incident window 21c. Can be reliably shut off. As a result, it is possible to remove noise components associated with the incidence of external light, and to increase the S / N ratio of the biological information signal corresponding to the light intensity of the reflected light. Therefore, measurement accuracy can be improved and more accurate biological information can be obtained. In addition, it cannot be overemphasized that the optical filter 21c3 can be provided in the flat transparent base material 21c1 like the entrance window 21c of the light receiver 21 in embodiment mentioned above.

  In carrying out the present invention, the present invention is not limited to the above-described embodiments and modifications, and various modifications can be made without departing from the object of the present invention.

  For example, in the embodiment and the modification described above, the light receiving device 21 that is electromagnetically shielded and integrally accommodates the amplifier 22 is used to detect the extremely weak reflected light that has propagated through the living body and to generate an electrical detection signal with a low impedance. This was applied to the biological information measuring device S that outputs the data. In this manner, the light receiver 21 that is electromagnetically shielded and integrally accommodates the amplifier 21 can block external electromagnetic waves and accurately detect extremely weak light and output a good detection signal. For this reason, it is of course possible to detect such extremely weak light by using such a light receiver 21 for measurement in other measurement objects or other measurement environments.

  In the embodiment and the modification described above, the baseband signal is modulated with the spread spectrum and the clock frequency 2f in consideration of the fact that the light is greatly attenuated by propagating in the living body and the measurement resolution of the living body information is increased. Based on the secondary modulation signal, the light emission timing of the light source 16 in each light emitting unit 1 was simultaneously emitted so as to emit modulated light. On the other hand, the light emission timing of the light source 16 in each light emitting unit 1 is varied at a predetermined short time interval according to the measurement target and measurement environment, and light such as near infrared light is emitted in pulses. It is also possible to do.

  In this case, in the light emitting unit 1, the spread code sequence generator 11, the first multiplier 12, and the second multiplier 14 are omitted, and the base bend output unit 13, the light source, as compared with the above-described embodiment and modification. The driver 15 and the light source 16 are included. Then, the control unit 31 of the controller 3 operates the baseband output device 13 at a predetermined timing, so that the light source driver 15 drives (emits light) the light source 16.

  In this case, the light detection unit 2 is also changed with the change of the light emitting unit 1. That is, in the light detection unit 2, the first multiplier 25, the second multiplier 26, and the accumulator 27 of the light detection unit 2 in the embodiment and the modification are omitted, and the light receiver 21, the amplifier 22, and the LPF 23. And an AD converter 24. As described above, even when the light emission timing of the light source 16 of the light emitting unit 1 is changed at predetermined short time intervals and light such as near infrared light is emitted in a pulsed manner, The same effect as the modification can be expected.

  In the embodiment and the modification, the light emitting unit 1 generates a secondary modulation signal obtained by modulating the baseband signal with the spread spectrum and the clock frequency 2f, and the two modulated lights are emitted without interfering with each other. Was carried out. On the other hand, the baseband signal from the baseband output unit 13 is frequency-division multiplexed (FDM) modulated to generate a modulated signal, and the interference between the two modulated lights is prevented. It is also possible.

  In this case, the spread code sequence generator 11, the first multiplier 12, and the second multiplier 14 are omitted from the light emitting unit 1 in the embodiment and the modification, and a frequency division multiplex modulator is provided. In this case, the first multiplier 25, the second multiplier 26, and the accumulator 27 of the light detection unit 2 in the embodiment and the modification are omitted, and a frequency division multiplex demodulator is provided. The operation of the frequency division multiplex modulator and the frequency division multiplex demodulator can be modulated and demodulated by applying a widely known method, and detailed description thereof is omitted. To do. In this way, even when the modulation signal is generated by frequency division multiplex modulation and the modulated light is emitted, the same effects as those of the above embodiment and the modification can be expected.

  Moreover, in the said embodiment and modification, it implemented so that the light source 16 of each light emission part 1 light-emitted simultaneously based on the secondary modulation signal by which the spread spectrum modulation was carried out. In this case, it goes without saying that the light source driver 15 can sequentially cause the light source 16 to emit light based on the secondary modulation signal subjected to spread spectrum modulation.

  In the embodiment and the modification, the living body information measuring device S uses the light absorption characteristic of blood in the living body to change the oxygenated hemoglobin concentration length change ΔCoxy and the reduced hemoglobin concentration length change ΔCdeoxy in the brain of the head T. Was measured (calculated) as biological information, and changes in blood flow in the brain were observed. However, by appropriately changing the specific wavelength of the near-infrared light generated by the light source 16 of the light emitting unit 1, other light absorption characteristics, for example, the density of the living body, moisture, glucose concentration in blood (blood glucose level), Needless to say, it is possible to measure absorption, for example, oxygen saturation, associated with changes in the amount of lipid or pulse.

Hereinafter, a case where the oxygen saturation level SO ₂ is measured (calculated) will be briefly described. In the above embodiment and the modification, the oxygenated hemoglobin concentration length change ΔCoxy and the reduced hemoglobin concentration length change ΔCdeoxy can be measured (calculated) using the above equations 4 and 5, whereby the total hemoglobin concentration length change ( ΔCoxy + ΔCdeoxy) can be measured (calculated). Then, by calculating these values, it is possible to measure (calculate) the relative oxygen saturation SO ₂ represented by the following formula 6.
SO ₂ = ΔCoxy / (ΔCoxy + ΔCdeoxy) (Formula 6)

Incidentally, the oxygenated hemoglobin concentration length change ΔCoxy and the reduced hemoglobin concentration length change ΔCdeoxy calculated as described above are calculated including the optical path length d, as is apparent from the equations 4 and 5. In general, as described above, it is difficult to accurately measure or calculate the optical path length of light incident on a living body due to the influence of irregular reflection or the like. Therefore, the optical path length d in the above formulas 4 and 5 is used as a relative quantity, and the oxygen saturation SO ₂ calculated by the above formula 6 using the oxygenated hemoglobin concentration length change ΔCoxy and the reduced hemoglobin concentration length change ΔCdeoxy. Is also a relative amount.

In this case, by calculating the oxygen saturation SO ₂ in accordance with the formulas shown below, without including the relative amounts of oxygen saturation SO ₂ in the pulsating component, in other words, the oxygen saturation SO of artery or arterioles ₂ can be calculated. The oxygen saturation calculation method is disclosed in, for example, Japanese Patent Laid-Open No. 63-111837 and is a widely known calculation method, and a detailed description thereof will be omitted.

The infrared attenuation level in the living body can be calculated according to the following formula 7.
−log (I1 / I0) = E × C × e + A Equation 7
However, I1 in the formula 7 represents the amount of transmitted light that has passed through the arteriole, and I0 represents the amount of incident light. E in Equation 7 represents the extinction coefficient of hemoglobin, C represents blood hemoglobin blood concentration, e represents the thickness of the blood layer (corresponding to the optical path length d in Equations 4 and 5), A Represents the degree of attenuation of the tissue layer. Here, Equation 7 is used to calculate the attenuation of infrared light transmitted through the living body, but it is known that even reflected infrared light exhibits similar characteristics.

If the blood layer thickness e is changed by Δe due to pulsation, the change in the infrared attenuation can be calculated according to the following equation (8).
− (Log (I1 / I0) −log (I2 / I0)) = E × C × e−E × C × (e−Δe) Equation 8
If the above equation 8 is arranged, the following equation 9 is obtained.
−log (I2 / I1) = E × C × Δe Equation 9
However, I2 in the above formulas 8 and 9 represents the amount of transmitted light after the change in the thickness of the blood layer.

Next, assuming that the wavelength of the infrared light having the transmitted light amount I1 is λ1, the wavelength of the infrared light having the transmitted light amount I2 is λ2, the light amounts of the transmitted light at λ1 at times t1 and t2 are I11, I21, λ2. Assuming that the amount of each transmitted light is I12 and I22, the change in the infrared attenuation at each time can be expressed by the following equations 10 and 11 according to the above equation 9.
−log (I21 / I11) = E1 × C × Δe Equation 10
−log (I22 / I12) = E2 × C × Δe Equation 11
However, −log (I21 / I11) = E1 × C × Δe in Equation 10 Equation 10
−log (I22 / I12) = E2 × C × Δe Equation 11
However, E1 in the formula 10 represents the extinction coefficient of hemoglobin with respect to the infrared light having the wavelength λ1, and E2 in the formula 11 represents the extinction coefficient of hemoglobin with respect to the infrared light having the wavelength λ2. Then, when the formula 11 is divided by the formula 10, the following formula 12 is established in which the blood layer thickness change Δe is eliminated.
log (I12 / I22) / log (I11 / I21) = E2 / E1 Equation 12
Therefore, if Equation 12 is modified, the following Equation 13 is established.
E2 = E1 × log (I12 / I22) / log (I11 / I21) ... Equation 13

Here, referring to the light absorption spectrum of hemoglobin corresponding to the oxygen saturation shown in FIG. 21, when 805 nm is selected as the absorption wavelength corresponding to the absorption coefficient E1 of hemoglobin, the oxygen saturation SO ₂ = 0% and the oxygen saturation Obtain the intersection of the curves of degree SO ₂ = 100%. As a result, the extinction coefficient E1 becomes a value that is not affected by the oxygen saturation. Then, for example, 750 nm is selected as the absorption wavelength corresponding to the absorption coefficient E2 of hemoglobin, and the absorption coefficient of hemoglobin when the oxygen saturation level SO ₂ = 0% is Ep and the oxygen saturation level SO ₂ = 100%. When the extinction coefficient of hemoglobin is E0, the current oxygen saturation SO ₂ can be calculated according to the following equation (14).
SO ₂ = (E2−Ep) / (E0−Ep) Equation 14
As a result, the oxygen saturation SO ₂ calculated according to the equation 14 is calculated without including a relative amount, so that the actual oxygen saturation can be obtained. Therefore, for example, more accurate oxygen saturation SO ₂ can be provided in diagnosis by a doctor.

  Furthermore, in the said embodiment and modification, the light receiver 16 which accommodated the light emitting element 16b in the case 16a, and the light receiver 21 which accommodated the photoelectric conversion element 21b in the case 21a were assembled | attached to the pallet member 51 of the holder 5, and it implemented. . In this case, for example, various elements such as a piezoelectric element, a thermoelectric element, and an imaging element are accommodated in a predetermined case, and the various elements accommodated in the case are assembled to the pallet member 51 of the holder 5 for implementation. It is also possible. In this case, it goes without saying that a case containing various elements can be assembled to the pallet member 51 of the holder 5 using the latch mechanism 6.

  Thus, even when various elements other than the light emitting element 16b and the photoelectric conversion element 21b are assembled to the pallet member 51 of the holder 5, the pallet member 51 is firmly attached to the measurement region of the head T that is the subject. Since it can be fixed, measurement, temperature measurement, and imaging using various elements can be performed more accurately. Further, by using the latch mechanism 6, it is possible to very easily attach and detach the case containing various elements with respect to the pallet member 51, so that accurate and quick measurement, temperature measurement, and imaging can be performed.

  DESCRIPTION OF SYMBOLS 1 ... Light emission part, 11 ... Spreading code sequence generator, 12 ... 1st multiplier, 13 ... Baseband output device, 14 ... 2nd multiplier, 15 ... Light source driver, 16 ... Light source, 16a ... Case, 16a1 ... Case main body, 16a2 ... case cap, 16a3 ... thin film conductive layer, 16a4 ... engagement projection, 16b ... light emitting element, 16c ... emission window, 16c1 ... transparent substrate, 16c2 ... transparent conductive film, 2 ... light detection unit, 21 ... Light receiver, 21a ... case, 21a1 ... case body, 21a2 ... case cap, 21a3 ... thin film conductive layer, 21a4 ... engagement projection, 21b ... photoelectric conversion element, 21c ... incident window, 21c1 ... transparent substrate, 21c2 ... transparent conductive Membrane, 22 ... Amplifier, 23 ... LPF, 24 ... AD converter, 25 ... First multiplier, 26 ... Second multiplier, 27 ... Accumulator, 3 ... Controller, 31 ... Control unit, 32 Clock generator 33 ... Delay 4 ... Display unit 5 ... Holder 51 ... Pallet member 51a ... Through hole 51b ... Adjustment unit 52 ... Belt member 52a ... First part 52b ... Second part 52c ... Connection part, 52c1 ... Slide part, 52d ... Perimeter adjustment mechanism, 52d1 ... Adjustment dial, 53 ... Connection member, 54 ... Guide member, 54a ... Guide member body, 54b ... Guide member nut, 6 ... Latch mechanism, 61 ... Latch Ring, 61a ... groove, 62 ... coil spring, S ... biological information measuring device

Claims (17)

In a holder for holding a plurality of elements and mounting them at a predetermined position on the subject's head,
A hard and thin pallet member formed with a plurality of through-holes for holding each of the plurality of elements and having a three-dimensional curved surface adapted to the curved shape of the averaged head; ,
A first portion arranged circumferentially corresponding to the position of the frontal bone in the skull forming the head of the subject, and a second portion arranged circumferentially corresponding to the position of the occipital bone in the skull A string that is arranged corresponding to the position of the temporal bone in the skull and includes a connecting portion that connects the first portion and the second portion to each other, and is fixed to the subject's head in a circumferential manner A belt member,
A circumference adjusting mechanism that is provided on the belt member and adjusts the circumference of the belt member in accordance with the circumference of the head of the subject;
A holder comprising a string-like connecting member that expands and contracts the pallet member and the belt member. The holder according to claim 1,
The pallet member is molded corresponding to each part of the head of the subject wearing the plurality of elements, and has a curved shape of the averaged head that is different for each part of the head. A holder characterized by being formed to have a combined three-dimensional curved surface. In the holder according to claim 1 or 2,
A holder provided with a guide member for holding the plurality of elements in a state preset in the head of the subject with respect to the plurality of through holes formed in the pallet member. In the holder according to claim 3,
The guide member holds at least the plurality of elements toward a predetermined reference point on the subject's head. In the holder according to any one of claims 1 to 4,
The connection part of the belt member has a curve formed so as to bypass the rear part of the pinna of the subject's ear, and connects the first part and the second part to each other. Holder. In the holder as described in any one of Claims 1 thru | or 5,
The pallet member is provided with an adjustment portion for finely adjusting a connection state with the connection member in the vicinity of a connection position with the connection member. In the holder according to any one of claims 1 to 6,
The circumferential length adjusting mechanism connects the second portions positioned at both ends of the belt member formed in a string shape so as to overlap each other, and slides the second portions stacked on each other in a relatively opposite direction. A holder that adjusts the circumference of the belt member in accordance with the circumference of the head of the subject. The holder according to claim 7,
The holder according to claim 1, wherein the circumferential length adjusting mechanism includes an adjustment dial that is rotated to slide the second portions of the belt member overlapped with each other in a relatively opposite direction. A holder according to any one of claims 1 to 8,
Light that emits near-infrared light having a different specific wavelength to the inside of the head of the subject by causing a light source having a light emitting element detachably held on the pallet member of the holder to emit light based on a predetermined drive signal An emission part;
Receives and detects near-infrared light emitted from the light emitting part and propagating through the inside of the subject's head through a light receiver having a photoelectric conversion element detachably held on the pallet member of the holder And an optical detection unit that outputs an electrical detection signal related to the metabolism of the living body corresponding to the light intensity of the near-infrared light detected,
A control unit that controls the operations of the light emitting unit and the light detection unit in an integrated manner and calculates biological information based on an electrical detection signal output from the light detection unit. Biological information measuring device. The biological information measuring apparatus according to claim 9,
The light source of the light emitting part is
A case main body having at least internal conductivity and grounded; a case cap having at least internal conductivity and assembled to the case main body; and optical transparency with respect to the specific wavelength and electrical conductivity. The light emitting element is housed and configured in a case that includes a window portion that is electrically connected to the case body and emits light.
The light receiver of the light detection unit is:
A case main body having at least internal conductivity and grounded; a case cap having at least internal conductivity and assembled to the case main body; and optical transparency with respect to a specific wavelength emitted from the light emitting portion A photoelectric conversion element and an electrical output output from the photoelectric conversion element in a case having a window portion that has electrical conductivity and is electrically connected to the case main body and receives light. A biological information measuring apparatus comprising: an amplification circuit that amplifies a detection signal and outputs the amplified electrical detection signal with an output impedance smaller than an output impedance of the photoelectric conversion element; . The biological information measuring device according to claim 10,
The inside of the case body and the inside of the case cap are a thin film conductive layer composed of a nickel (Ni) layer subjected to strike plating and a copper (Cu) layer or a gold (Au) layer electrolessly plated on the nickel (Ni) layer. A layer is formed,
The window is formed with a transparent conductive film mainly composed of indium-tin oxide (ITO), zinc oxide (ZnO) or niobium oxide (NbO),
The biological information measuring device, wherein the thin film conductive layer and the transparent conductive film are electrically connected. The biological information measuring device according to any one of claims 9 to 11, wherein the biological information calculated by the control unit is:
The activity in the brain of the subject calculated based on the information indicating the oxygenated hemoglobin concentration length change combined with oxygen in the blood vessel of the subject's head and the reduced hemoglobin concentration length change not combined with oxygen A biological information measuring device characterized by being biological information. The biological information measuring apparatus according to any one of claims 9 to 12,
The light emitting part is
Spread spectrum modulation means for performing spread spectrum modulation on the predetermined drive signal;
The light detection unit is
A biological information measuring apparatus comprising demodulating means for demodulating the electrical detection signal by despreading the spectrum. The biological information measuring device according to claim 13,
Spread spectrum modulation means of the light emitting part,
A spread code sequence generating means for generating a spread code sequence for performing spread spectrum modulation on the predetermined drive signal with a first frequency, and the predetermined drive using the spread code sequence generated by the spread code sequence generating means Modulating the primary modulation signal output by the first modulation means by using a first modulation means for spectrum-spreading the signal and outputting a primary modulation signal, and a second frequency that is twice the first frequency And second modulation means for outputting a secondary modulation signal,
The demodulating means of the light detection unit is
Signal component removing means for removing and outputting signal components at DC and frequencies near DC, and signal components at or above the second frequency in the signal band of the electrical detection signal, and the near infrared light Is an electrical detection signal output by the signal component removing means using a third frequency that is twice the second frequency, taking into account the delay associated with propagating through the subject's head. Digital signal converted by the signal conversion means using the signal conversion means for converting to a digital signal and the second frequency taking into account the delay associated with propagating the near-infrared light inside the head of the subject. The primary demodulation using a first demodulation means for demodulating a signal and outputting a primary demodulated signal, and the spread code sequence taking into account the delay associated with propagating the near infrared light inside the subject's head Trust Biological information measuring apparatus characterized by a second bi-tonal means for outputting a secondary demodulated signal by spectrum despreading. In the biological information measuring device according to claim 14,
The biological information measuring apparatus according to claim 1, wherein the second frequency is matched with an effective detection bandwidth in which the light detection unit can effectively detect near-infrared light propagating through the head of the subject. The biological information measuring apparatus according to any one of claims 9 to 12,
The light emitting part is
The predetermined drive signal supplied with a predetermined time interval is acquired, the light source sequentially emits light based on the acquired predetermined drive signal, and the near infrared light having the different specific wavelength is A biological information measuring device which emits sequentially with a predetermined time interval. The biological information measuring apparatus according to any one of claims 9 to 12,
The light emitting part is
Frequency division multiplexing modulation means for generating a modulation signal by frequency division multiplexing modulation of the predetermined drive signal;
The light detection unit is
A biological information measuring device comprising a double tone means for frequency division multiplexing demodulation of the electrical detection signal.

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