CONFIGURABLE PHOTOELECTRIC CELL

Abstract

Photoelectric cell with means of configuring the operating mode. The cell has several optosensitive zones 11, 12, D capable of outputting magnitudes that are activated or processed in different manners, by configuration and/or processing means 7, 19. The cell may thus be used in reflex mode, proximity mode or proximity with background elimination mode. Amplifying parts 16a, 16b are provided at the side of the optosensitive zones to amplify electrical magnitudes before routing them to the microcontroller 19 in the processing circuit 6.

Description

[0001] This invention relates to a photoelectric cell designed for detection of an object, comprising an optical component equipped with a photosensitive area that generates an electrical reception signal on a conductor as a function of the incidence of an optical beam, and an amplification and processing circuit generating an output signal that depends on the electrical signal.

[0002] This type of photoelectric cell is well known. When they operate by detection of a light flow originating from infinity without any proximity effect, they form part of a first family of cells called reflex, polarized reflex or barrage cells. When they operate by detection of light rays at high incidence, they form part of a second family of cells operating either by measurement of energy in a “proximity” subfamily, or by triangulation, comparing two channels of a PSD type component in a “proximity with background elimination” subfamily. Detection modes for these two families will be referred to as “reflex mode” and “proximity mode” in the rest of this document, for simplicity. Cells in the first family are used particularly to detect the presence of an object, whereas cells in the second family are used particularly to detect the distance or brightness of an object.

[0003] The optical components necessary to make these two families are different. Their surface area is small, typically of the order of 0.6×0.6 mm for reflex cells, but larger and typically with apparent size 1.6×1.6 mm for proximity cells or 1×2 mm for proximity with background elimination cells. The result is that several types of components need to be procured and stored (typically at least three different components) in order to manage these two product families.

[0004] Furthermore, magnetic compatibility constraints affecting photoelectric cells are increasing, whereas the optical components that use them at the present time have the disadvantage than they offer low intrinsic amplification in the case of phototransistors, and even zero amplification in the case of photodiodes.

[0005] The purpose of this invention is to overcome these disadvantages by using simple arrangements that can be taken particularly on the optosensitive component or the processing circuit, so that it becomes easier to make a photoelectric cell insensitive to parasites and capable of operating in different operating modes in order to offer different detection possibilities.

[0006] According to a first aspect of the invention, the photoelectric cell comprises configuration means capable of acting on the photosensitive area or the processing circuit in response to a means of selecting a reflex operating mode or a proximity operating mode for the cell.

[0007] According to a second aspect of the invention, the photosensitive area is separated by separation into at least two adjacent partial areas isolated from each other, each of these partial areas being capable of supplying electric magnitudes to one of the two channels connected to the amplification and processing circuit, and configuration means are provided to select the operating mode specified for the cell; these configuration means are preferably capable of activating and/or processing electrical magnitudes output from the partial areas, for example by means of switches and/or a microcontroller, as a function of the selected operating mode.

[0008] Preferably, and when it is required to configure the cell in reflex mode and in proximity mode, the adjacent partial areas are capable of outputting electrical magnitudes to a first conductor and a second conductor connected to the channel and configuration means are provided to activate the first conductor in reflex mode and the second conductor in proximity mode; the photosensitive area used in proximity mode may itself be separated by a demarcation transverse to separation, into isolated adjacent areas that are connected to the respective channels and the surface area of which varies continuously along the main direction of the component, this direction being the direction of displacement of the optical spot of the incident beam on the photoreceptive area in proximity mode.

[0009] Preferably, and when it is required to configure the cell in proximity mode or in proximity with background elimination mode, the photosensitive area used may be separated by demarcation transverse to the main direction, into isolated adjacent zones, the surface area of which varies continuously along the main direction of the component, which is an integrated component preferably comprising two amplifying parts of the amplification and processing circuit at the side of the photosensitive area, that amplify the signal originating form the partial areas or photosensitive zones and which are connected through the respective channels to a remaining part of the amplification and processing circuit that controls the configuration described above.

[0010] A more detailed description will now be made of a non-restrictive embodiment of the invention, with reference to the attached drawings.

[0011] FIG. 1 diagrammatically shows a photoelectric cell.

[0012] FIG. 2 shows the composition of an optoreceptive component of a photoelectric cell according to the invention.

[0013] FIGS. 3 and 4 show the optoreceptive component configured in reflex mode and in proximity mode.

[0014] FIG. 5 shows a variant of the component according to the invention.

[0015] FIG. 6 shows another variant.

[0016] FIG. 7 shows one form of construction of the configuration means;

[0017] FIG. 8 shows an example of processing applied to voltage signals output by the component.

[0018] The photoelectric cell illustrated In FIG. 1 comprises an electronic circuit 1 that generates electrical emission pulses and an emission diode 2 that emits a light beam collimated by a lens 3. The cell emission assembly does not form part of the invention and will not be described further. The cell also comprises firstly a reception assembly provided with a lens 4 that focuses the received light beam as a function of the presence of an object, an optosensitive device 5 that transforms the received light flux into an electrical magnitude, and an electronic reception circuit 6 that amplifies and processes this magnitude to generate an output signal S that depends on whether or not an object is present. The cell is connected through a link with two or three wires to an energy source E and a load L.

[0019] As will be described later, the cell is capable of operating either in reflex mode or in proximity mode as defined above, under the control of configuration means 7.

[0020] In the photoelectric cell shown (see FIG. 2), the optosensitive device 5 forms part of an integrated type unit component C that also comprises an amplifying part of the electronic reception circuit. The integrated component C is provided with a photoreceptive area 10 that extends along an X direction corresponding to the direction of displacement of the optical spot during movement of an object to be detected in proximity mode. The photoreceptive area 10 is formed on the surface of an appropriate optosensitive material; it currently operates in photodiode, but it could also operate differently and is separated into two areas 11, 12 isolated from each other and adjacent in the X direction. The areas 11, 12 are isolated along a separation line 14 perpendicular to the X direction.

[0021] The partial areas 11, 12 are separated by a demarcation 15 located in skew, for example diagonal, into zones of adjacent isolated trapezoidal or triangular photodiodes D1a, D1b and D2a, D2b respectively, the surface area of which varies approximately continuously along the X direction. This variation may be linear or non-linear. The integrated component C comprises lateral amplifying areas 16a, 16b adjacent to the photosensitive area 10, that are located on the two opposite sides of the component and that at least partly (as we will see later) perform the amplification function for circuit 6. Two connecting channels A, B connect zones 16a and 16b to the rest of circuit 6. The photodiode zones D1a, D2a of areas 11, 12 are connected in parallel to channel A through conductors 11a, 12a, whereas the photodiode zones D1b, D2b of areas 11, 12 are connected in parallel to channel B through conductors 11b, 12b; conductors 12a, 12b are fitted with electronic switches 13a, 13b respectively, acted upon by configuration means 7 to control whether or not these zones are activated.

[0022] Currents Ia, Ib transported by conductors 11a, 12a, and 11b, 12b are conducted to amplifying circuits and appropriate ambient light suppressers 17a, 17b located in zones 16a, 16b, and voltages Va, Vb are created on channels A, B which are analyzed in an appropriate part of the electronic reception circuit 6. Consequently (see FIG. 8), circuit 6 comprises for example a sampler-blocker 18 and a microcontroller 19 with an integrated digital-analog converter 20, the reference input 20a of this converter being connected to a programmable voltage regulator 21 that forms part of the configuration means 7. The voltage regulator 21 outputs different voltage levels in reflex and in proximity mode, in response to a reflex/proximity operation signal transmitted by the microcontroller through a line 19a following a configuration order Sc output by a switch or a connection wire.

[0023] Apart from programmable voltage regulator 21, the configuration means 7 may comprise (see FIG. 7) a comparator 22, a fixed voltage V0 being applied to one of the inputs of this comparator and a voltage Vcc output by the programmable voltage regulator 21 being applied to the other input. The configuration may be switched through any usual electronic or mechanical means.

[0024] As shown in FIG. 5, the photosensitive areas 11, 12 may each be separated into more than two zones by several separations 15. Area 11 (zones D1a, D1b) may be located as shown at the center of the component along the X direction, whereas the area 12 (zones D2a, D2b) and another zone 12′ (zones D'2a, D'2b) are located on opposite sides of zone 11 along the X direction.

[0025] The photosensitive zones D may be inter-digitate as shown in FIG. 6 to adapt the cell to a light spot smaller than the width of the photosensitive area 10. ln this case the area 10 is separated into several rectangles 23 each composed of two triangles 23a, 23b or other zones with surface areas gradually increasing or decreasing along the X direction and with appropriate geometry; triangles 23a being connected to channel A and triangles 23b being connected to channel B.

[0026] Depending on the case, the photoelectric cell described may operate in reflex mode or in proximity mode with the same receiving lens 4, or with different lenses.

[0027] The photoelectric cell described operates as follows.

[0028] In order to operate in reflex mode, the signal Sc with a specific logic level is transmitted to the microcontroller 19, and the microcontroller switches the programmable voltage regulator 21 through line 19a; the regulator 21 outputs its first voltage level and switches 13a, 13b are open (FIG. 3). Only photodiodes D1a, D1b output a current when the photosensitive surface 10 receives the light flux. The voltages Va, Vb resulting from the amplification in amplifiers 17a, 17b are summated by the processing circuit 6, and the output signal switches as a function of the value of this sum.

[0029] In order to operate in proximity mode, the signal Sc with the inverse logical level is transmitted to the microcontroller 19 and the microcontroller switches the programmable voltage regulator through line 19a; the regulator 21 outputs its second voltage level and switches 13a, 13b are closed (FIG. 4). All photodiodes D1a, D1b and D2a, D2b output current and voltages Va, Vb are either summated by the microcontroller 19 in the processing circuit 6 (operation in proximity), or are compared with each other by the microcontroller 19 (operation in proximity with background elimination) and the output signal switches as a function of the value of this sum or the result of the comparison.

[0030] When it is required to make the cell operate in proximity and proximity with background elimination modes only, line 19a may be omitted and the configuration is made using signal Sc by the microcontroller 19 that decides to summate the voltage signals originating from the various photosensitive zones, or to compare the signals on channels A and B, depending on the required mode.

Claims

1. Photoelectric cell designed for detection of an object, comprising an optical component equipped with a photoreceptive area (10) that generates an electrical reception signal on a conductor as a function of the incidence of a light beam, and comprising an amplification and processing circuit (6) that generates an output signal (S) that depends on the electrical reception signal, characterized by configuration means capable of acting on the photoreceptive area (10) or on the processing circuit (6) in response to a means of selecting a reflex operating mode or a proximity operating mode for the cell.

2. Photoelectric cell designed for detection of an object, comprising an optical component equipped with a photoreceptive area (10) that generates an electrical reception signal on a conductor as a function of the incidence of a light beam, and comprising an amplification and processing circuit (6) that generates an output signal (S) that depends on the electrical reception signal, characterized by the fact that the photosensitive area (10) is separated by a separation (14) into at least two partial areas (11, 12; Da, Db) adjacent to but isolated from each other and capable of outputting electrical magnitudes on the two channels (A, B) respectively connected to the amplification and/or processing circuit (6), and configuration means (7, 19) are provided to activate and/or process the magnitudes output by the partial areas as a function of a proximity operating mode or another operating mode selected for the cell.

3. Cell according to claim 2, characterized by the fact that the adjacent partial areas (11, 12) are capable of supplying electrical magnitudes on a first conductor (11a, 11b) and a second conductor (12a, 12b) respectively, connected to channel (A, B) and configuration means (7) are provided to activate the first conductor in reflex mode and the second conductor in proximity mode.

4. Cell according co claim 3, characterized by the fact that the component (C) has a main direction (X) which is the direction of displacement of the light spot of the incident beam on the photoreceptive area (10) in proximity mode, the photosensitive area (11, 12) used in proximity mode itself being separated by a demarcation (15) transverse to the separation (14), into isolated adjacent zones (Da, Db) that are connected to the respective channels (A, B) and the surface area of which varies continuously in the main direction (X).

5. Cell according to claim 3, characterized by the fact that the configuration means (7) comprise a comparator (22), a voltage (Vcc) being applied to the input of the comparator that is different in reflex mode and in the proximity mode, and the output of which is connected to the electronic switch (13a, 13b).

6. Cell according to claim 2, characterized by the fact that the component (C) is an integrated component comprising two amplifying parts (16a, 16b) of the amplification and processing circuit (6) at the side of the photosensitive area (10), which amplifies the signal originating from the photosensitive zones and which are connected through channels (A, B) respectively to a remaining part (19) of the amplification and processing circuit (6).

7. Cell according to claim 2, characterized the fact that the amplification and processing circuit (6) comprises a sampler-blocker (18), the input of which is connected to the output channels (A, B) from component (C) and the output of which is connected to a microcontroller (19) which is used with a digital-analog converter (20), the configuration means comprising a programmable device (21) connected to the microcontroller and to the said converter.

8. Cell according to claim 4, characterized the fact that the photosensitive zones (D) are inter-digitate in zones (23a, 23b) connected to channels (A, B) respectively.

9. Photoelectric cell designed for detection of an object, comprising a component equipped with a photosensitive area (10) that generates an electrical reception signal on a conductor as a function of the incidence of an optical beam, and comprising an amplification and/or processing circuit (6) that generates an output signal (S) that depends on the electrical reception signal, the component (C) with a main direction (X) which is the direction of displacement of the optical spot of the incident beam on the photosensitive area (10) in proximity mode, characterized by the fact that: the photosensitive area (10) used in proximity mode is separated by a demarcation (15) transverse to the main direction (X) into isolated adjacent zones (Da, Db), the surface of which varies continuously along the main direction (X), the component (C) is an integrated component comprising two parts (16a, 16b) of the amplification and/or processing circuit (6) at the side of the photosensitive area (510), and these two part amplify the signal transferred from the respective adjacent zones (Da, Db) that are connected through the corresponding channels (A, B) to a remaining part (19) of the amplification and processing circuit (6).