法国专利FR3036195A1 DEVICE AND METHOD FOR OBSERVING AN OBJECT, WITH ACCOUNT OF THE DISTANCE BETWEEN THE DEVICE AND THE O

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专利摘要:
The invention relates to the field of endoscopic or laparoscopic in vivo fluorescence measurements. The device of the invention comprises a source of excitation light, illuminating an object, in particular a biological tissue and inducing emission of emission light by the examined object. The emission light is for example a fluorescence light. The device makes it possible to obtain an image of the biological tissue examined, from the emission light. The device also includes a telemetry sensor, emitting a light beam telemetry to the object. A projector element makes it possible to project the excitation beam and the telemetry beam directly onto the object. The telemetry sensor estimates a distance between the projector element and the object. The measurement of this distance makes it possible to modulate an intensity of the excitation light emitted by the object. When the object is a biological tissue, it allows on the one hand to respect thresholds of illumination of biological tissues, and, on the other hand, to maintain an illumination of constant intensity. The projector element may in particular be included at the end of a laparoscope or an endoscope. One of the applications of the invention is medical fluorescence imaging, endoscopically or laparoscopically.
公开号:FR3036195A1
申请号:FR1554259
申请日:2015-05-12
公开日:2016-11-18
发明作者:Philippe Rizo
申请人:FLUOPTICS；Commissariat a lEnergie Atomique CEA；Commissariat a lEnergie Atomique et aux Energies Alternatives CEA；
IPC主号:

专利说明:

[0001] 1 Apparatus and method for observing an object, taking into account the distance between the device and the object. Description FIELD OF THE INVENTION The field of the invention is the imaging performed on objects, in particular using endoscope or laparoscope-type light guides. The objects may in particular be body tissues. Imaging can be fluorescence imaging for the diagnosis and monitoring of the evolution of pathologies or treatments.
[0002] PRIOR ART Fluorescence imaging is a technique for locating fluorescent markers in a human or animal body. An application is the localization of fluorescent markers, or fluorophores, the latter targeting cells of interest, for example cancer cells. The protocol consists of injecting these markers into the body before surgery, so that during the intervention, the practitioner is able to visualize the cancer cells using a fluorescence image. . Because it allows to acquire an image indicating the localization of the different cancerous areas, the intraoperative fluorescence imaging allows to obtain information hitherto inaccessible to the practitioner, and constitutes a useful complement, even an alternative, to the use of radioactive tracers. Another application is assistance with interventions in cardiovascular surgery, lymphatic surgery, or liver surgery, where fluorescence imaging allows visual monitoring of drainage, perfusion, or vascularization. The principle of fluorescence imaging is to illuminate a field of view using a light source in a spectral band of fluorophore excitation. Under the effect of this illumination, the fluorophores emit fluorescence radiation, in a spectral band of fluorescence. This radiation can be captured by a fluorescence camera, so as to form a fluorescence image on which appear the different fluorescent zones. It is then possible to acquire a visible image of the observed field, and to superimpose the fluorescence image on this visible image.
[0003] One mode of application of fluorescence imaging is the endoscopic or laparoscopic pathway, making it possible to acquire fluorescence images of a biological tissue within an organism, via a minimally invasive pathway. . For example, US20130184591 describes a laparoscope comprising a distal end intended to be introduced into an organism, close to the examined tissue, and a proximal end intended to be kept outside the body.
[0004] The proximal end is connected to a light source, producing an excitation beam for the emission of fluorescence light by fluorophores potentially present in the tissue, the markers being previously introduced into the organism to be examined. It is also connected to a visible light source. At its proximal end, the laparoscope further includes a visible image sensor and a fluorescence image sensor. Optical spectral separation means for directing the visible light reflected by the biological tissue as well as the fluorescence light respectively to the visible image sensor and the fluorescence image sensor. The transmission of fluorescent light and visible light from the examined tissue to the proximal end requires a collection optical system, located at the distal end, to collect the optical signals in a certain field of view. It also requires an optical transmission system, or optical relay, to transmit the fluorescence and visible lights to their respective image sensors, arranged at the proximal end. Due to the small opening of these optical systems, the amount of fluorescence signal at the proximal end is small. It can be increased by increasing the intensity of the excitation beam. This raises the problem of the risk of drying or burning of the tissue examined, because of the increase of the excitation light signal. In particular, when the excitation beam is produced by a laser source, it is necessary to comply with regulatory requirements, for example the international standard IEC 25 60825-1, relating to the safety of laser devices. The device described in this document allows a control of the exposure of the tissue by analyzing the signals detected by the image sensors housed in the proximal end of the laparoscope. But a control of tissue exposure by an image sensor lacks precision. The inventors have devised a device and a method for observing an object, in particular a body tissue, and in particular endoscopically or laparoscopically, making it possible to acquire a fluorescence image, while ensuring that the illumination of the fabric being examined complies with the 3036195 3 requirements in force with respect to the integrity of these fabrics, ensuring good safety of use. SUMMARY OF THE INVENTION An object of the invention is an observation device of an object comprising: an excitation light source capable of producing an excitation beam, in an excitation spectral band, propagating itself to said object, a transmission image sensor, capable of collecting a transmission light emitted by said object, under the effect of said excitation beam, in a spectral emission band, the image sensor transmitter being able to acquire an emission image from the collected emission light, a distance sensor comprising a telemetry light source, capable of producing a telemetry beam, in a spectral range of telemetry, propagating towards the object, the distance sensor also comprising a telemetry light sensor, able to detect a telemetry light reflected by the object, the device being characterized in that it comprises: a projecting element r, configured to project said excitation beam and said telemetry beam towards the object at a solid projection angle. The distance sensor being able to measure a distance between said projector element and said object, a modulator, configured to modulate an intensity of the excitation beam, as a function of said distance measured by the distance sensor. The device may in particular comprise a light guide, extending between a proximal end and a distal end, the light guide being able to transmit: the excitation beam and the telemetry beam from said proximal end to said end distal, - said emission light and said telemetry light reflected from the object of said distal end to said proximal end, the distal end of said light guide having said projector element. In particular, the distal end is intended to be introduced into the body of a human or animal, so as to be arranged facing the object to be examined. The object to be examined is in particular a biological tissue, in particular a body tissue.
[0005] The light guide may be a laparoscope or an endoscope. The light guide may comprise, at its distal end, an optical system capable of collecting the emission light and the telemetry light from the object, so as to direct them towards the proximal end of the light guide. . This optical system can include a lens or a lens. This optical system defines a solid observation angle whose intersection with the object forms the observed field. This optical system may also be able to direct said excitation beam and said telemetry beam towards said object, said optical system then forming the projector element. The light guide may include at least one transmission optical fiber, extending between the proximal end and the distal end of the light guide, so as to guide the excitation beam and the telemetry beam between said end. proximal and said distal end, the end of each a transmission optical fiber at said distal end forming the projector element. Preferably, the projector element directs the excitation beam and the telemetry beam at the same solid projection angle.
[0006] The projection of the excitation beam and the telemetry beam defines a field illuminated on the object. Preferably, the illuminated field is coincident with or inscribed in the field observed. The light guide may comprise a spectral separator, capable of directing: the emission light towards the emission image sensor, the telemetry light reflected by the object towards the telemetry light sensor.
[0007] The spectral separator, the emission image sensor and the telemetry light sensor may be housed at the proximal end of the light guide, for example in a detection module located at this proximal end. The device may comprise: a visible light source, able to produce a visible light beam towards said object in a visible spectral band, a visible image sensor, capable of collecting visible light reflected by the object under the effect of an illumination by said visible light beam, the visible image sensor 5 being able to acquire a visible image from the collected visible light, the light guide then being able to transmit: said visible light beam of the light; proximal end towards the distal end, and said visible light reflected by the object from the distal end to the proximal end.
[0008] The visible image sensor may be housed at the proximal end of the light guide, for example in the detection module integrated at this proximal end. The telemetry light source can be confused with the excitation light source. In this case, the distance measurement is carried out using the propagation of the excitation light from the excitation light source towards the object as well as the propagation of the excitation light reflected by the object between this object. last and the telemetry light sensor. The spectral telemetry band may be different from the excitation spectral band and the emission spectral band, or even the visible spectral band. The distance sensor may comprise: a splitter, able to return a portion of said telemetry beam, emitted by the telemetry source, to a trigger photodetector, the latter being able to detect said portion of the telemetry beam returned by said splitter a telemetry processor, able to determine said distance of the telemetry beam path between the telemetry light source and the telemetry sensor, based on a trigger timing, at which the trigger photodetector 25 detects said telemetry beam and a stop time, at which said telemetry light sensor detects said telemetry light reflected by the object, the telemetry processor being able to determine said distance between the projector element and the object from the distance of travel of the telemetry beam.
[0009] 3036195 6 The trigger photodetector and the telemetry processor can be included in the light guide. Another object of the invention is a method of observing an object comprising the following steps: illuminating an object with a telemetry light beam, produced by a telemetry light source, in a spectral band telemetry, the illumination beam being projected onto the object by a projector element defining a solid projection angle, - detecting a telemetry light reflected by the object, in said spectral range of telemetry, as a function of said detected telemetry light, measuring a distance between the projector element and the object, illuminating said object with the aid of an excitation beam emitted by a source of excitation light, in a spectral band of excitation, said excitation beam 15 being projected onto the object by said projector element, according to said solid projection angle, detection of an emission light by a transmission image sensor, ladi the emission light being emitted by the object under the effect of said illumination by the excitation beam; acquisition of an emission image by said emission image sensor from said light of said emission light; detected emission, the method being characterized in that it also comprises: the modulation of an intensity of the excitation beam, as a function of the distance measured.
[0010] Modulation of the intensity of the excitation beam can be achieved by modulating a control signal of the excitation light source or by interposing an attenuator between the excitation light source and the object. According to one embodiment, the excitation beam and the telemetry light beam are transmitted to the object by a light guide, a distal end of which, including the projector element, is placed in front of the light beam. object, the light guide also ensuring the transmission of said emission light emitted by the object and said telemetry light reflected by the object respectively to the emission image sensor and the light sensor of telemetry. The emission image sensor and the telemetry light sensor may in particular be arranged at the proximal end of the light guide, for example in a detection module integrated in this proximal end.
[0011] The emission light emitted by the object and the telemetry light reflected by the object can be collected by an optical system located at the distal end of the light guide, before being returned to the sensor respectively. transmission image and telemetry light sensor. The optical system defines a field observed on the object, as previously defined.
[0012] This optical system, which may in particular comprise an objective or a lens, defines an observed field on the object, corresponding to a surface of the object from which the emission light and the telemetry light collected by the optical system originate. According to one embodiment, the excitation beam and the telemetry beam are projected onto the object by said optical system, the latter then forming said projector element.
[0013] According to one embodiment, the excitation beam and the telemetry beam are projected onto the object by at least one optical fiber, extending between the proximal end and the distal end of the light guide. end of each optical fiber at said distal end forming the projector element. According to one embodiment, the emission light is a fluorescence light, in a spectral emission band, or fluorescence spectral band, different from the excitation spectral band. According to one embodiment, the emission light corresponds to a reflection or excitation beam on the object and / or a backscattering of the excitation beam in the object. The emission spectral band therefore corresponds to the excitation spectral band.
[0014] According to one embodiment, the method also comprises: the illumination of the object by a visible light beam produced by a visible light source, in a visible spectral band, in particular through the light guide, 5; acquisition of a visible image of the object using a visible image sensor, the latter detecting a visible light reflected by the object, in particular through the light guide. According to one embodiment, the telemetry light source is merged with the excitation light source, the spectral telemetry band then corresponding to the excitation spectral band. According to one embodiment, the spectral telemetry band is different from the excitation spectral band and the emission spectral band, or even the visible spectral band. Another object of the invention is a device comprising: a distance sensor comprising a telemetry light source, capable of producing a telemetry beam, in a spectral telemetry band, propagating towards the object; distance also comprising a telemetry light sensor, able to detect a telemetry light reflected by the object, the device being characterized in that it comprises: a light guide, extending between a proximal end and an end distal, the light guide being adapted to transmit the telemetry beam from said proximal end to said distal end, as well as said telemetry light reflected by the object from the distal end to said proximal end, - the distal end of said distal end light guide having a projector element for projecting said telemetry beam towards the object at an angle solid projection, - the distance sensor being able to measure a distance between said projector element and said object.
[0015] In particular, the distal end is intended to be introduced into the body of a human or an animal, so that it can be arranged in particular facing the object to be examined. The object to be examined is in particular a biological tissue, in particular a body tissue. The light guide may in particular be a laparoscope or an endoscope.
[0016] The light guide may comprise, at its distal end, an optical system capable of collecting the telemetry light from the object, so as to direct it towards the proximal end of the light guide. This optical system can include a lens or a lens. This optical system defines a solid angle of observation, whose intersection with the object forms the observed field.
[0017] Preferably, the surface of the object is divided into surface elements. The distance sensor is then able to measure a distance between said projector element and each surface element. The distance sensor may in particular comprise a matrix photodetector, comprising a plurality of pixels, and is capable of determining a distance between each pixel and each surface element to which said pixel is optically coupled.
[0018] According to one embodiment, the device comprises a processor, connected to the distance sensor, and able to establish a three-dimensional mapping of the observed field. The telemetry light sensor may in particular be disposed at the proximal end of the light guide, for example in a detection module included in this proximal end.
[0019] The device may comprise: a source of excitation light capable of producing an excitation beam, in an excitation spectral band propagating towards an object, a transmission image sensor, capable of collecting a light of emission emitted by said object, under the effect of said excitation beam, in a transmission spectral band, the emission image sensor being able to acquire an emission image from the light of collected emission, the light guide being adapted to transmit said excitation beam to the object and to transmit said emission light reflected by the object to said emission image sensor. The latter can in particular be arranged in the light guide, in particular at its proximal end. Another object of the invention is a method comprising the following steps: illumination of an object by a telemetry light beam, produced by a telemetry light source, in a spectral range of telemetry, the beam of illumination being projected onto the object by a projector element defining a solid projection angle, - detection of a telemetry light reflected by the object, in said spectral range band 10, as a function of said detected telemetry light, measurement a distance between the projector element and the object, the method being characterized in that: - the telemetry beam is transmitted to the object by a light guide, including a distal end, comprising the projector element, is placed facing the object, - the light guide also ensuring the transmission of said telemetry light reflected by the object to the light sensor of t lémétrie. The telemetry light reflected by the object may be collected by an optical system located at the distal end of the light guide, before being returned to the telemetry light sensor. The optical system defines a field observed on the object, as previously defined. According to one embodiment, the surface of the object is divided into surface elements. The method then comprises a step of measuring the distance between said projector element and each surface element. According to this embodiment, the distance sensor may in particular comprise a matrix photodetector. The matrix photodetector has a plurality of pixels, so as to determine a distance separating each pixel from the surface element to which said pixel is optically coupled.
[0020] According to this embodiment, the method may comprise performing a three-dimensional mapping of the observed field, as a function of the measured distance corresponding to each surface element. The method may comprise the following steps: illumination of said object with the aid of an excitation beam emitted by an excitation light source, in an excitation spectral band, said excitation beam being projected onto the an object by said projector element, according to said solid projection angle, detecting an emission light by an emission image sensor, said emission light being emitted by the object under the effect of said illumination by the excitation beam; acquisition of a transmission image by said emission image sensor from said detected emission light. According to this variant, the excitation beam can be transmitted to the object by said light guide, the latter also ensuring the transmission of said emission light emitted by the object to the image sensor. 'program. FIGURES FIG. 1A represents a first embodiment of a device according to the invention. Figures 1B and 1C show a detail of the distal end of the light guide in two different variants. Figure 1D shows a detail of the distal end of the light guide and the object. Figure 2 shows a detail of the structure of the distance sensor. Figure 3 shows a detail of the proximal end of the light guide. FIG. 4 represents the steps of a method according to the invention.
[0021] Figure 5 shows a second embodiment of a device according to the invention. FIG. 6 represents a variant of the first or second embodiment of a device according to the invention.
[0022] FIG. 7 represents another variant of the first or second embodiment of a device according to the invention. FIG. 8 represents another variant of the first or second embodiment of a device according to the invention.
[0023] Figure 9 shows an experimental setup. FIG. 10 represents the results of a test carried out by implementing the experimental setup described in FIG. 9. FIG. 11 represents a third embodiment of a device according to the invention.
[0024] DESCRIPTION OF PARTICULAR EMBODIMENTS FIG. 1 shows a device 1 according to a first embodiment. The device comprises a source of excitation light 11, able to emit an excitation light beam 12, in an Xex excitation spectral band, so as to illuminate an object 10. The object 10 is for example a biological tissue exposed to device 1 during an endoscopic or laparoscopic procedure. The term spectral band refers to the set of wavelengths within a specified range, between a minimum wavelength and a maximum wavelength. The excitation light source 11 may be continuous, amplitude modulated, or pulsed.
[0025] In this example, the excitation light source 11 is a pulsed laser diode emitting at a wavelength λex = 750 nm. It can also be a light-emitting diode. The light source may comprise an excitation filter, capable of blocking wavelengths outside the Xex excitation spectral band. The device comprises a light guide 2, having a proximal end 3 and a distal end. 5. The light guide allows the transmission of light between the proximal end 3 and the distal end 5 and vice versa. This light guide is, in this example, a laparoscope. It can also be an endoscope. The proximal end 3 comprises an input window 3a, able to receive light beams intended to be transmitted to the distal end 5. The proximal end 3036195 13 also comprises a detection module 3b, allowing the detection of light rays collected by the distal end 5. In this example, the excitation light beam emitted by the light source 11 is transmitted by an excitation optical fiber 11f (or a plurality of excitation optical fibers), transporting the excitation beam between the excitation light source 11 and an optical coupler 15. A coupling optical fiber 15f, or a plurality of coupling optical fibers 15f, transports the excitation beam 11 between the optical coupler 15 and the input optical window 3a. The latter comprises an optical connector allowing the transmission of the excitation beam in the light guide 2.
[0026] The light guide 2 comprises a central section 4, extending between the proximal end 3 and the distal end 5, so as to transmit a light between these two ends. In the example shown, the central section 4 comprises a plurality of transmission optical fibers 4f intended for the transmission of the excitation light beam 12 between the proximal end 3 and the distal end 5. The central section 4 also comprises a Relay optical element 4a, known per se, comprising for example relay lenses, and capable of transferring a light, and especially an image, between the distal end 5 and the proximal end 3, and vice versa. The optical fibers 4f are, for example, distributed around the periphery of the relay section, the relay optical element 4a being disposed in the central part of the central section 4. Generally, the light guide 2 comprises several tens or even hundreds of optical fibers. 4f transmission. According to one variant, the central section is flexible and comprises a bundle of optical fibers. The diameter of the central section is generally less than 1 or 2 cm. The length of the central section is for example between 10 and 30 cm when the light guide is rigid, for example when it is a laparoscope. In the case of an endoscope, the length of the guide may exceed 1 meter, or even several meters. The distal end 5 is intended to be introduced into the body of an animal or a human. It comprises a projector element intended to project the excitation beam 12 onto the object 10. The light is emitted, from the projector element, according to a transmission cone defining a solid projection angle SI. The emission with the object 10 corresponds to the illuminated field SQ.
[0027] By projector element is meant an optical element for projecting a beam of light onto the object, according to a transmission cone. It may especially be the end of one or more optical fibers or an optical system of the lens or lens type. In the example shown in FIG. 1A, the distal end 5f of each transmission optical fiber 4f opens out at the distal end 5 of the guide. The projector element is then constituted by the set of distal ends 5f of each transmission optical fiber 4f. Fig. 1B shows the distal end of the corresponding pattern light guide depicted in Fig. 1A. The light guide is also capable of transmitting light collected from the distal end 5 to the proximal end 3, through the central section 4. Thus, the distal end 5 comprises a distal optical system 5a having a collection function of light radiation from the field of view 10 located opposite the distal end 5. Thus, the distal optical system 5a defines a solid observation angle S2 ', whose intersection with the surface of the object constitutes the observed field So '. The light collected at the distal end 5, by the distal optical system 5a, can be transferred by the relay optical element 4a to a detection module 3b, integrated at the proximal end 3. 3b detection has the function of detecting the light collected from the distal end 5 towards the proximal end 3. Under the effect of the illumination by the excitation beam 12, the object 10 emits a light 20 emission 14 in a spectral emission band Xem. The emission light 14 may be a part of the illumination beam 12 reflected or backscattered by the object 10, the emission spectral band Xen, then being analogous to the Xex excitation spectral band. According to the example shown in FIG. 1A, the emitting light 14 is a fluorescence light, emitted by the object, in a fluorescence wavelength λf 0 different from the excitation wavelength λx. The object 10 comprises one or more endogenous or exogenous fluorophores. In the case where the fluorophores are endogenous, we speak of autofluorescence. The exogenous fluorophores are previously injected into the object, so as to bind specifically to targets, for example cancer cells. Each fluorophore is capable of emitting fluorescence radiation 14, in the Xfluo fluorescence spectral band, when it is illuminated by an excitation light 12, in an Xex excitation spectral band. For example, when the fluorophore used is indocyanine green, or ICG (Indocyanine 3036195 Green), the excitation spectral band can be between 750 nm and 800 nm, the fluorescence spectral band being between 820 nm and 870 nm. Thus, under the effect of the excitation beam transmitted by the distal end 5 of the guide 2, the object can emit a fluorescence light 14. In the example shown, the object 10 comprises a fluorescent zone 13, adapted to emit such a fluorescence light 14. A part of the latter is collected by the distal optical system 5a, then transferred, through the relay section 4, to a detection module 3b, included in the proximal end 3. The detection module 3b comprises a spectral separator 6, able to direct an incident light beam in a given direction as a function of its spectral band. The spectral separator 6 directs the emission light 14 to a transmission image sensor 16. The emission image sensor is able to form an image / of the emission light 14 produced by the emission light. object 10 under the effect of illumination by the excitation beam 12 emanating from the distal end 5. This image sensor 16 will be detailed later. A processor 50 is able to process the transmission images / in, formed by the image sensor 16.
[0028] This is for example a microprocessor integrated into a computer. In particular, the processor is a microprocessor connected to a programmable memory in which is stored a sequence of instructions for performing the image processing operations. These operations are for example the elimination of certain background noise, colorization or superposition with other images, as described later.
[0029] A screen 55, connected to the processor, makes it possible to display the images collected by the image sensor 16 and processed by the microprocessor 50. According to one variant, represented in FIG. 1C, the central section 4 does not include transmission optical fibers. 4f, the excitation beam being transmitted by the relay optical element 4a between the proximal end 3 and the proximal end 5. In such a variant, the distal optical system 5a performs the beam element function of the beam of excitation on the object 10, by defining a solid projection angle SI It is understood that according to this variant, the solid projection angle Q is equal to the solid observation angle S2 ', the illuminated and observed fields being confused. The device also comprises a distance sensor 20. The latter is based on the well-known principle of time-of-flight optical telemetry, which consists of evaluating the duration between the emission of a light pulse and the detection. of this impulse. This duration is representative of the distance traveled by the light forming the pulse between its emission and its detection. The distance sensor 20 comprises a light source 21, said telemetry light source, and adapted to emit a telemetry light beam 22 in a spectral telemetry band Xd. The light source 21 is preferably impulse. It emits light pulses, or telemetry pulses, at a pulse frequency that can be between 1 Hz and 100 Hz or even 1 kHz. In this example, the light source 21 is a pulsed laser diode emitting at a wavelength λd = 950 nm. It is controlled by a telemetry processor 51. The spectral telemetry band Xd can be below 400 nm or above 900 nm, so as to be located neither in the visible spectrum, nor in a spectral emission band (and in particular a spectral band of fluorescence). Thus, the telemetry light is not detected by the visible or emission image sensors. The telemetry light beam 22 passes through a light distributor 28, able to direct a first portion of the telemetry beam towards the light guide 2, through a telemetry optical fiber 21f, or a plurality of telemetry optical fibers 21f. Each telemetry fiber is connected to the light guide 2 by the optical coupler 15, from which the optical coupling fiber 15f opens. This optical fiber allows the transmission of the excitation beam 12 and the telemetry beam 22 to the entrance window 3a of the light guide. The optical coupler 15 makes it possible to guide the excitation and telemetry beams in the same optical fiber or in the same bundle of optical fibers, up to the light guide 2.
[0030] A second part of the telemetry beam 22 is directed towards a trigger photodetector 23. Preferably, the second part of the telemetry beam is a minority relative to the first part, and does not represent more than 20% or 10% of the telemetry beam. The trigger photodetector 23 is for example a photodiode, for example an avalanche photodiode whose bandwidth is adapted to the Xd-3036195 telemetry spectral band. As shown in FIG. the detection of a pulse by the trigger photodetector 23 triggers, in the telemetry processor 51, the activation of the incrementation of a telemetry counter 53 at a clock frequency, the latter rising for example to 20 MHz. This telemetry counter is included in the telemetry processor. Like the excitation beam 12, the telemetry beam 22 is directed towards the object 10 in the light guide 2 through the entrance window 3a. It then reaches the distal end 5 being transmitted by the transmission fibers 4f, from the end of which it is transmitted towards the object 10 according to an identical, or substantially similar, emission cone to the cone 10 In the variant shown in FIG. 1C, the telemetry beam 22 is transmitted to the distal end 5 by the optical relay 4a and, likewise, that the excitation beam 12 is projected onto the object by the distal optical system 5a. Due to the difference in wavelength of the excitation beam 12 and the telemetry beam 22, differences may appear between the emission cone of the excitation beam and the emission cone of the telemetry beam. However, these differences can be neglected and it can be considered that these two emission cones form a single cone defining the same solid projection angle SI It is also a remarkable advantage of the invention.
[0031] Alternatively, the excitation optical fiber 11f and the telemetry optical fiber 21f extend to the optical window 3a. However, it is preferable to have an optical coupler 15 between, on the one hand, the telemetry light source 12 and the excitation light source 11 and, on the other hand, the light guide 2. The optical coupler Its function is to couple the excitation optical fiber and the telemetry optical fiber with an optical coupling fiber, the latter being able to transmit the two beams to the light guide. Thus, the illumination of the object, by one or other of these beams, is similar, both in terms of the extent of the spatial distribution of the illumination on the object. A portion of the telemetry beam 22 reaches the object 10 and is reflected by the latter, thereby forming a reflected telemetry light 24. Part of this reflected light 24 is collected by the distal optical system 5a, and is then returned by the optical relay 4a to the detection module 3b, at the proximal end 3. In the detection module 3b, the spectral separator 6 directs the reflected telemetry light 24 to a telemetry light sensor 26. For example, a light sensor may be a photodiode, and in particular an avalanche photodiode, similarly to the triggering photodetector 23 previously described. Since the emission of the telemetry light beam 22 is impulse, it is the same for the detection of the telemetry light reflected by the object. When a pulse is detected by the telemetry light sensor 26, the incrementation of the telemetry counter 53 is stopped. The value of the counter, that is to say a number of increments between its activation, triggered by the trigger photodetector 23, and its stop, triggered by the telemetry light sensor 26, makes it possible to measure a distance D traveled. by the telemetry pulse 22, between the telemetry light source 21 and the telemetry photodetector 26 as shown in FIG. 2. This measurement can be performed by the telemetry processor 51 by implementing a telemetry device 22. type TDC, acronym for Time to Digital Converter. This processor can in particular be implanted in a telemetry microcontroller.
[0032] The estimation of the distance d between the distal end 5 of the guide, and more precisely of the projector element 5f, and the object 10 is carried out by the telemetry processor 51, as a function of the dimensions of the light guide. and in particular the distances traveled by the telemetry light respectively between the telemetry source 21 and the distal end 5 as well as between the distal end 5 and the telemetry sensor 26. This determination can be made on the basis of a calibration, making it possible to estimate this distance d as a function of the measurement made by the distance sensor 20. An example of calibration is shown in FIG. 10. It is also possible to measure a distance 6 traversed by the beam of excitation 22 between the excitation source 21 and the object 10. On the basis of the estimate of the distance d between the projector element 5f and the object 10, the telemetry processor 51 sends a signal of controlling a modulator 18 to modulate the intensity of the excitation beam emitted by the excitation source 11, so that the power delivered by the excitation beam 12 on the object is less than a maximum authorized power Pmax, this to avoid any risk of damage to the object by the excitation beam, especially when the object is a body tissue. For example, at Xe> = 750 nm, the maximum pfd is 0.25 W / cm2. This intensity adjustment is based on the closest distance d in the field of view between the object and the distal end of the excitation guide. At each distance d corresponds to a maximum permissible power per unit area Pmaxd, this maximum power can be determined experimentally and then tabulated in a memory. The adjustment of the beam intensity can be achieved by modulating a control signal of the excitation light source. It can also be achieved by arranging attenuators, where optical densities, on the path of the excitation beam. Note the similarity of the optical paths of the telemetry beam 22 and the excitation beam 12 in the light guide 2. These two beams are projected by the projector element 5f (or, where appropriate 5a) on the object according to Thus, and this is an important element of the invention, the surface of the object illuminated by the excitation beam 12 corresponds to the surface illuminated by the telemetry beam 22. Also, the measured distance d depends on the point M of the object 10 closest to the distal end 5. This property is particularly useful when the object 10 is not plane, and is likely to include, in the same observed field, near areas and areas remote from the distal end 5. Because the telemetry beam 22 is distributed at the same solid angle Q as the excitation beam, the measured distance is the closest distance, in the field observ e, between the object and the distal end 5 (or between the object and the excitation source 11). The adjustment of the power of the excitation beam is thus made based on the point of the observed field and which, receiving the excitation beam, is closest to the distal end 5.
[0033] This aspect is illustrated in FIG. 1D, showing an object whose surface is not flat. This surface is illuminated by the excitation beams 12 and telemetry 22, through the projector element 5f, under the same solid projection angle SI. The emission light 14 (in this case, a fluorescence light ) and the telemetry light 24 reflected by the object are collected by the distal optical system 5a at the same observation solid angle S2 '. The point M corresponds to the point of the surface of the object closest to the distal end 5. Following the illumination of the surface of the object by the telemetry beam 22, the point M is the first point of the the illuminated surface. As a result, the first ray of telemetry reflected by the object is the radius 24M. The latter is collected by the distal optical system 5a, then returned to the detection module 3b, to be detected by the telemetry photodetector 26. The telemetry counter 53 is then stopped. The distance D measured, representative of the optical path of the telemetry beam between the telemetry source 21 and the telemetry photodetector 26, therefore depends on the point of the surface of the nearest object 3036195 20 of the projector element located at the distal end 5 of the light guide 2, in this case the point M. It is the same for the distance d determined, from D, between the distal end 5 and the object 10. Whatever the In one embodiment, the solid projection angle S2 is preferably less than or equal to the observation solid angle S2 '. Advantageously, the solid projection angle S2 coincides with the solid observation angle S2 ', so that the illuminated field So corresponds to the observed field So-. Indeed, the distance measurement is performed on the surface of the object located in the area of coverage of the illuminated field So and the observed field SQ-.
[0034] In the example shown, the triggering of a pulse by the telemetry light source 21 is controlled by the telemetry processor 51. It is also possible, knowing this distance d, to modulate the excitation beam 12 of such so that the illumination generates a constant pfd, called the target power, at the point of the object 10 closest to the light guide, independently of the position of the distal end 5 with respect to the object 10. For this, the modulator 18 adjusts the intensity of the excitation beam with respect to a reference distance dref so that whatever the distance d between the distal end and the object, the pfd P delivered on the object is constant. For example, if Pref denotes the target power, the intensity of the beam is modulated, knowing the distance d, by a distance-dependent modulation function fd, such that fd (P) = Pref- Visible image The device may also comprise a visible light source 31, able to direct a visible light 32, in a visible spectral band X ,,, 'to the object 10, through a visible optical fiber 31f and the light guide 2.
[0035] The visible light source 31 may in particular be a source of white light, continuous or impulse. In this example, the visible light source is a white electroluminescent diode. Part of the visible light is reflected by the object and is collected by the distal optical system 5a to be returned to the proximal end 3 of the light guide 2, and more precisely to the detection module 3b. The spectral separator 6 directs the reflected visible light 34 to a visible image sensor 36, the latter forming a visible image k ,,,.
[0036] The processor 50 is able to process the visible images it, ', formed by the visible image sensor 36, by applying image processing operations. A processing operation is, for example, the superposition with a transmission image / from the transmission image sensor 16, the transmission image being previously colorized. The screen 55 makes it possible to display the visible image and / or the image obtained following the superposition. Note that the triggering of the telemetry light source 21 may be performed synchronously with the visible light source 31, or asynchronously. When the telemetry spectral band Xd has wavelengths of the visible spectral band X, the telemetry light source 12 is triggered synchronously with the times at which the visible light source 31 is turned off. Detection module FIG. 3 depicts an example of a detection module 3b, forming part of the proximal end 3 of the light guide 2. The spectral separator 6, previously mentioned, is intended to send different light beams back to a specific detector in depending on their wavelength, using semi-reflective plates, or dichroic plates, transmitting light in a given spectral band and reflecting the light in another spectral band. A first semi-reflecting plate 6.1 transmits the light in the emission spectral band ile ', as well as in the spectral telemetry band. This first plate reflects light 34 in the visible spectral band towards a mirror 6.4, the latter reflecting the light. visible light towards the visible image sensor 36. This image sensor comprises a matrix photodetector 39, coupled to a focusing optical system 35. A second semi-reflecting plate 6.2 transmits the light in the Xd spectral range band to a beam. telemetry light sensor 26 and reflects the light in the spectral emission band to a mirror 6.3, the latter reflecting the emission light 14 to a transmission image sensor 16. This image sensor transmission 16 comprises a matrix photodetector 19, coupled to a focusing optical system 15. When the emission light is a fluorescent light, the spe band The emission crystal is a fluorescence spectral band 2 μm, the emission image sensor 16 being a fluorescence image sensor. In this case, preferably, the fluorescence image sensor 16 comprises a fluorescence filter 17, the bandwidth of which is defined as a function of the XfIuo fluorescence spectral band. The function of this fluorescence filter is to prevent the detection, by the fluorescence image sensor, of optical radiation that is not representative of the fluorescence.
[0037] The visible and transmission matrix photodetectors 19 and 19 are CCD (charge coupled device) type sensors of the CMOS type (acronym meaning Complementary Metal-Oxide Semiconductor), or even a bolometer. particularly in the case of fluorescence in an infrared spectral band.
[0038] The telemetry light sensor 26 includes a telemetry photodetector 29 capable of detecting light radiation in the Xd telemetry spectral band. It may also include a telemetry filter 27 whose bandwidth is defined according to the Xd spectral telemetry band. The function of this telemetry filter is to avoid the detection of optical radiation that is not representative of the telemetry light 24 reflected by the object. It may also include focusing optics 25, especially when the telemetry photodetector 29 is a matrix photodetector, this case being detailed later. FIG. 4 summarizes the main steps of the method implemented in this example: Step 100: emission of a telemetry beam 22, in the form of a pulse, by the telemetry light source 21. This transmission causes the detection of this pulse by the trigger photodetector 23 and the activation of the telemetry counter 53. Step 200: detection of a telemetry light 24 reflected by the object 10, by the telemetry sensor 26, which causes the stopping the telemetry counter 53 and determining the distance D traveled by the telemetry light between the telemetry source 21 and the telemetry sensor 26. Step 300: Based on this distance D, determining the distance d between the telemetry light 21 and the telemetry sensor 26. distal end 5 of the guide 2 and the object, according to which modulation of the excitation beam 12 emitted by the excitation source 11 is effected, taking into account a lightning power permissible Pmax by the object or a reference power Pref.
[0039] Step 400: emission of the excitation beam 12 by the excitation source 11, and detection of a transmission image lem, for example an Ifluo fluorescence image, by the emission image sensor 16. This step may also include the emission of visible light 32 from the visible light source 31, and the detection of a visible image by the visible image sensor 36. The use of transmission optical fibers 4f, in the light guide 2, to direct the excitation beam 12 and the telemetry beam 22 towards the object 10 is judged preferable to a configuration in which these beams are directed towards the object by the optical relay 4a. Indeed, according to this last configuration, illustrated in FIG. 1C, parasitic reflections 10 can occur in the optical relay 4a, inducing a potential inadvertent detection of a telemetry light by the telemetry sensor. Such inadvertent detection results in erroneous distance measurement. In general, it is preferable that the optical paths taken by the excitation beam 12 and the telemetry beam 22 are different from those taken by the emission light 14 and the telemetry light 24 reflected by the object. FIG. 5 represents another embodiment, according to which the excitation source 11 is pulsed and constitutes the telemetry light source 21. Thus, the Xd spectral range corresponds to the Xex excitation spectral band. This limits the number of light sources implemented in the device. In such a configuration, the excitation light source is preferably pulse. A part of this beam is directed towards the triggering photodetector 23 by the splitter 28, which has the effect of activating the telemetry counter 53. The other part is propagated towards the object 10 through the light guide 2 The object reflects a portion of the excitation beam and this excitation (or telemetry) light 24 reflected by the object is transmitted to the telemetry sensor 26. Some elements of the distance sensor 20 may be integrated. in the light guide, for example at the detection module 3b of the proximal end 3. Figure 6 shows an example of such an integration. In this figure, the trigger photodetector 23 is integrated in the detection module 3b, as is the telemetry processor 51. This supposes a connection by an optical fiber 28f between the distributor 28 and the trigger photodetector 23. This embodiment makes it possible to reduce the length of the electrical connections between the key elements of the distance sensor 20, namely the trigger photodetector 23, the telemetry sensor 26 and the telemetry processor 51. This improves the accuracy of the measurement. measured. According to another variant, shown in FIG. 7, the telemetry light source 21, the distributor 28, the trigger photodetector 23 and the processor are integrated in the detection module 3b, forming part of the proximal end 3 of the detector. 2. A semi-reflecting mirror 6.5 makes it possible to direct the telemetry light beam 22, produced by the telemetry light source 21, towards the distal end 5 of the light guide, through the optical element of FIG. relay 4a. This semi-reflecting mirror also allows transmission of the emission light 14, or telemetry 24 or visible lights 34 reflected by the object 10, propagating from the distal end 5 towards the spectral separator 6. variant allows complete integration of the distance measuring sensor 20 in the proximal end of the light guide 2. This provides a particularly compact device.
[0040] The variant shown in FIG. 8 is similar to that shown in FIG. 7, the transmission of the telemetry beam 22 between the telemetry light source 21 and the object 10 being carried out by the excitation optical fibers 21f, coupling 15f, and 4f transmission. In the configurations shown in FIG. 7 or FIG. 8, the excitation source 11 can also be accommodated in the guide 2, in particular at its proximal end 3.
[0041] An experimental test was carried out, using the device shown in FIG. 9. A commercial optical distance meter TO is placed facing a mirror M, opposite which an optical fiber FO is arranged, the latter being connected to the input window. 3a of a laparoscope 2. The rangefinder emits a telemetry light beam capable of being collected by the optical fiber FO, and transmitted by the laparoscope to a target T. The optical rangefinder TO comprises a photodetector, the latter being arranged facing the detection module 3b of the laparoscope. The photodetector of the rangefinder detects the telemetry light reflected by the target T, transmitted by the laparoscope. In this example, the detection module consists of a simple transparent window. The length of the optical fiber FO is 2.5 m.
[0042] FIG. 10 shows the distance D measured by the range finder, corresponding to the optical path of the telemetry light beam, as a function of the distance d between the distal end 5 of the laparoscope 2 and the target T. This figure shows that the Measuring the measured distance D allows an accurate estimation of the distance d as long as the distal end of the laparoscope is more than 15 mm away from the object. The fluctuations occurring when d <15 mm are due to inhomogeneous illumination of the target when the latter is placed too close to the distal end. Fig. 11 shows another embodiment in which the surface of the object is divided into a plurality of elementary surfaces. According to this embodiment, it is not sought to establish the closest distance between the distal end 5 of the light guide 2 and the surface of the object, as in the embodiments described above, but to obtain the 10 distances between the distal end 5 and each surface element. The telemetry sensor 26 comprises a matrix photodetector 29, each pixel of which is capable of establishing a measurement of the distance separating it from the surface element from which it is optically coupled, that is to say of the surface element. conjugate of this pixel. Such a photodetector may for example be a 3D time-of-flight camera, for example the SR4000 model marketed by Mesa Imaging. Such a camera comprises a pulsed source of telemetry light 21, for example in the form of a light emitting diode emitting in a spectral band Xd centered on the 850 nm wavelength. The telemetry light beam is directed to the object 10 through the optical relay 4a, and then the distal optical system 5a. The reflected telemetry light 20 is collected by the distal optical system 5a and then returned to the photodetector 29 through the optical relay 4a. The photodetector is able to determine the time elapsed between the telemetry light pulse 22 by the light source and the detection of this pulse on each of these pixels. This provides a measure of the distance traveled by the telemetry light between the object and each pixel of the telemetry light sensor 26, from which the distance between the distal end 5 of the guide 2 and each surface element. Such a device then makes it possible to obtain a three-dimensional representation of the object 10 located opposite the distal end 5. It can allow the preparation or the follow-up of delicate interventions, requiring precise information of the dimensions of the device. object. It may for example be surgical procedures, in which certain sensitive organs must not be touched by surgical tools. The three-dimensional data relating to the examined body tissue can be transmitted to a haptic interface, in order to provide assistance to the surgical procedure, whether robotic or manual. This haptic interface can in particular alert the surgeon when a surgical tool is near a sensitive organ. We then understand the advantage of having three-dimensional data of the observed field in real time. Preferably, the device represented in FIG. 11 comprises an excitation light source, as previously described, capable of generating an excitation beam 12. The excitation beam is guided by the light guide 2 up to the distal end 5. The emission light emitted by the object as a result of this excitation is then collected by the distal optical system 5a, and sent back to the transmit image sensor 16. A processor 54 may allow the processing or displaying the three-dimensional data transmitted by the telemetry image sensor 26 as well as the image generated by the emission image sensor 16. The excitation light source 11 can be replaced by a visible light source 31. Similarly, the transmission image sensor 16 can be replaced with a visible image sensor 36.
[0043] The device can in particular integrate the characteristics of the devices presented in the previous embodiments as soon as they are technically compatible. Beyond the laparoscopes, the invention applies to any endoscope or, in general, to any image acquisition device, in particular a fluorescence image, in response to a light excitation. 20

权利要求:
Claims (23)
[0001]
REVENDICATIONS1. Apparatus (1) for observing an object (10) comprising: an excitation light source (11) adapted to produce an excitation beam (12) in a propagation spectral band (Xex) propagating to an object, a transmission image sensor (16), able to collect a transmission light (14) emitted by said object (10), under the effect of said excitation beam (12), in a emission spectral band-er, 1 the emission image sensor being able to acquire a transmission image (lem, 1 from the collected emission light, - a distance sensor (20) comprising a telemetry light source (21), capable of producing a telemetry beam (22), in a spectral telemetry band (Xd), propagating towards the object (10), the distance sensor also having a telemetry sensor (21); telemetry light (26), able to detect a telemetry light (24) reflected by the object (10), the device being characterized in that i 1 comprises: a projector element (5a, 5f), configured to project said excitation beam (12) and said telemetry beam (14), towards the object, at a solid projection angle (Q); distance (20) being able to measure a distance (d) between said projector element (5a, 5f) and said object, a modulator (18), configured to modulate an intensity of the excitation beam (12), according to said distance (d) measured by the distance sensor (20).
[0002]
2. An observation device according to claim 1, comprising a light guide (2) extending between a proximal end (3) and a distal end (5), the light guide being able to transmit: the beam of light excitation (12) and the telemetry beam (22) from said proximal end (3) to said distal end (5), - said emission light (14) and said telemetry light emitted by the object ( 24) from said distal end (5) to said proximal end (3), the distal end (5) of said light guide (2) having said projector element (5a, 5f).
[0003]
3. Observation device according to claim 2, wherein the light guide comprises, at its distal end (5), an optical system (5a) able to collect the emission light (14) and the light. telemetry device (24) from the object (10) to direct them to the proximal end (3) of the light guide.
[0004]
4. Device according to claim 3, wherein said optical system (5a) is able to direct said excitation beam (12) and said telemetry beam (22) towards said object (10), the optical system (5a). then forming the projector element.
[0005]
5. Device according to claim 2 or claim 3, wherein: the light guide (2) comprises at least one transmission optical fiber (4f), extending between the proximal end (3) and the distal end of the light guide (2), so as to guide the excitation beam and the telemetry beam between said proximal end (3) and said distal end (5), the end of each one transmission optical fiber (4f ) at said distal end (5) forming the projector element (5f).
[0006]
6. Device according to any one of claims 2 to 5, wherein the light guide comprises a spectral separator (6), adapted to direct: the emission light (14) to the emission image sensor (16), the telemetry light (24) reflected by the object (10) to the telemetry light sensor (26).
[0007]
7. Device according to any one of claims 2 to 6 comprising: a visible light source (31), able to produce a visible light beam (32) towards said object (10) in a visible spectral band (Xvis), a visible image sensor (36), able to collect a visible light (34) reflected by the object under the effect of illumination by said visible light beam (32), the visible image sensor 3036195 29 being adapted to acquire a visible image (I'is) from the visible light collected, and wherein the light guide (2) is able to transmit: - said visible light beam (32) of the proximal end (3) to the distal end 5 (5) - and said visible light (34) reflected by the object (10) from the distal end (5) to the proximal end (3).
[0008]
8. Device according to any one of the preceding claims, wherein the telemetry light source (21) is merged with the excitation light source (11). 10
[0009]
9. Device according to any one of claims 1 to 7, wherein the spectral range of telemetry (Xd) is different from the excitation spectral band (Xex) and the emission spectral band (Xem).
[0010]
10. Device according to claim 7, in which the spectral telemetry band (Xd) is different from the excitation spectral band (Xex) and the emission spectral band (Xem) as well as from the visible spectral band. (X ,,, $).
[0011]
11. Device according to any one of the preceding claims, wherein the distance sensor (20) comprises: a splitter (28), able to return a portion of said telemetry beam (22), emitted by the telemetry source (22). ), towards a trigger photodetector (23), the latter being able to detect said part of the telemetry beam returned by said distributor (28), a telemetry processor (51), able to determine said distance (D) of course the telemetry beam (22), between the telemetry light source (21) and the telemetry sensor (26), as a function of a triggering time, at which the trigger photodetector (23) detects said telemetry beam (22) and a stop time, at which said telemetry light sensor (26) detects said telemetry light reflected by the object, the telemetry processor (51) being able to determine e distance (d) between the projector element (5a, 5f) and the object (10) as a function of said distance (D) of travel of the telemetry beam.
[0012]
The device of claim 11, wherein the trigger photodetector (23) and the telemetry processor (51) are included in the light guide (2).
[0013]
13. A method of observing an object comprising the steps of: illuminating an object (10) with a telemetry light beam (22) produced by a telemetry light source (21) in a band telemetry spectral range (Xd), the illumination beam being projected onto the object by a projector element (5a, 5f), at a solid projection angle (Q), detection of a reflected telemetry light (24) by the object, in said spectral telemetry band (Xd), as a function of said detected telemetry light (24), measuring a distance (d) between the projector element (5a, 5f) and the object ( 10), illuminating said object (10) with an excitation beam (12) emitted by an excitation light source (11), in an excitation spectral band (Xex), said beam excitation being projected onto the object by said projector element (5a, 5f), according to said solid projection angle (Q). detecting a transmission light (14) by a transmission image sensor (16), said emission light (14) being emitted by the object (10) under the effect of said illumination by the excitation beam (12), acquisition of a transmission image (lem, / flue) by said emission image sensor (16) from said detected emission light (14), the method characterized in that it further comprises: - modulating an intensity of the excitation beam (12) as a function of the distance (d) measured.
[0014]
The method of claim 13, wherein: the excitation beam (12) and the telemetry light beam (22) are transmitted to the object (10) by a light guide (2), a distal end (5) comprising the projector element (5a, 5f) is placed facing the object (10), the light guide also transmitting said emission light (14) emitted by the object and said telemetry light (24) reflected by the object respectively to the transmission image sensor (16) and the telemetry light sensor (26).
[0015]
The method according to claim 14, wherein the emission light (14) emitted by the object and the telemetry light (24) reflected by the object are collected by an optical system (5a) 10 located at the distal end (5) of the light guide (2), before being returned to the emission image sensor (16) and the telemetry light sensor (26).
[0016]
The method according to claim 15, wherein the excitation beam (12) and the telemetry beam (14) are projected onto the object (10) by said optical system (5a), the latter forming said projector element ( 5a). 15
[0017]
17. A method according to claim 14 or claim 15, wherein the excitation beam (12) and the telemetry beam (14) are projected onto the object (10) by at least one optical fiber (4f), extending between the proximal end (3) and the distal end (5) of the light guide (2), the end of each optical fiber at said distal end (5) forming said projector element (5f). 20
[0018]
18. A method according to any one of claims 13 to 17, wherein the emission light is a fluorescence light in a fluorescence spectral band (Xfii, o) different from the excitation spectral band (Xex).
[0019]
19. The method of any one of claims 13 to 17, wherein the emission light corresponds to a reflection or backscattering of the excitation beam by the object (10).
[0020]
The method according to any one of claims 14 to 19, further comprising: illuminating the object with a visible light beam (32) produced by a visible light source (31), in a visible spectral band across the light guide (2) 3036195 32 acquisition of a visible image (Iyis) of the object (10) using a visible image sensor (36), the latter detecting a visible light reflected by the object (34) through the light guide (2).
[0021]
21. A method according to any of claims 13 to 20, wherein the telemetry light source (21) is merged with the excitation light source (11), the telemetry spectral band (Xd). corresponding then to the excitation spectral band (Xex).
[0022]
22. A method according to any one of claims 13 to 20, wherein the spectral range of telemetry (Xd) is different from the excitation spectral band (Xex) and the emission spectral band (Xem) - 10
[0023]
23. The method of claim 20, wherein the spectral range of telemetry (Xd) is different from the excitation spectral band (Xex), and the emission spectral band (Xern) as well as the visible spectral band ( ,,, $ X).

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US20170074652A1|2014-04-22|2017-03-16|Basf Se|Detector for optically detecting at least one object|FR3075960B1|2017-12-22|2020-06-19|Commissariat A L'energie Atomique Et Aux Energies Alternatives|DEVICE FOR MEASURING RADIATION RETRODUCTED BY A SAMPLE AND MEASURING METHOD USING SUCH A DEVICE.|

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2016-11-18| PLSC| Publication of the preliminary search report|Effective date: 20161118 |

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优先权:

申请号 | 申请日 | 专利标题

FR1554259A|FR3036195B1|2015-05-12|2015-05-12|DEVICE AND METHOD FOR OBSERVING AN OBJECT, WITH ACCOUNT OF THE DISTANCE BETWEEN THE DEVICE AND THE OBJECT.|

FR1554259|2015-05-12|FR1554259A| FR3036195B1|2015-05-12|2015-05-12|DEVICE AND METHOD FOR OBSERVING AN OBJECT, WITH ACCOUNT OF THE DISTANCE BETWEEN THE DEVICE AND THE OBJECT.|

PCT/FR2016/051115| WO2016181077A1|2015-05-12|2016-05-11|Device and method for observing an object, taking into consideration the distance between the device and the object|

US15/573,372| US20180132708A1|2015-05-12|2016-05-11|Device and method for observing an object, taking into consideration the distance between the device and the object|

EP16729959.3A| EP3294111B1|2015-05-12|2016-05-11|Device and method for observing an object, taking into consideration the distance between the device and the object|

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