DE2458946C2 - Optical analog read-only memory - Google Patents

Description

can be.

The light source 6 and the Fptodiode 7 are rigidly connected to a piston 3 of a hydraulic cylinder 9. This hydraulic cylinder 9, which is also fixedly attached to the support body 5, can be subjected to air or oil pressure via a pressure line 10, for example, which is dependent on the position of the throttle valve in the air intake pipe or the gas pedal of an internal combustion engine. Depending on the air or oil pressure present on the pressure line 10, the reading device having the light source 6 and the photodiode 7 can be shifted back and forth in the radial direction with respect to the flat main surfaces 2a and 2b of the glass pane 2.

A further reading device is attached to the support body 5 in a stationary manner with respect to the ^ bearing body 4, which also has a light source II and a light-sensitive element, e.g. B. a phototransistor 12 has. The glass pane 2 is also arranged at its edge between the light source 11 and the x> phototransistor 12 so that the light beam emitted by the light source 11 to the phototransistor V1 is perpendicular to the flat main surfaces 2a and 26 of the glass pane 2 and penetrates this glass pane 2 Glass pane 2 can therefore also influence the intensity of the light beam striking phototransistor 12.

Wave 3 of the analog read-only memory according to FIG. 1 can e.g. B. are driven by the crankshaft of the internal combustion engine. The disc 2 to then rotates at the speed of the internal combustion engine. Thus, a relative movement is carried out between the disk 2 serving as a data carrier and the reading device having the light source 6 and the photodiode 7. Angular and circumferential)> speed of the disk 2 and thus the speed of this relative movement are thus assigned to the speed of the internal combustion engine; When the accelerator pedal or the throttle valve is adjusted, the piston 8 with the reading device having the light source 6 and the photodiode 7 is moved radially to the main surfaces 2a and 2b of the disk 2. A relative movement 4 is thus also carried out between the disk 2 and the reading device, the direction of which deviates from the direction of the rotational movement of the disk 2. The elongation of the radial movement of the piston 8 with the reading device is assigned to the respective accelerator pedal or throttle valve position, which represents a further operating parameter of the internal combustion engine.

A photographic surface coating with non-uniform blackening, ie non-uniform light transmission, is arranged on the flat main surface 2a. In Figure 2, a ring sector 13 of this surface coating is indicated, in which the light transmission is uneven. In the direction of rotation, this ring sector 13 is preceded by a further narrow ring sector 14 with the same inner and outer radius, in which the photographic coating has a uniform blackening and thus a uniform light transmission. Between the two ring sectors 13 and 14 and at the edge and in the center of the disk 2 is not a photographic surface coating is present, that the disk 2 ^pl there is strong and uniformly translucent. At the edge, however, the disk 2 has, within the angle of the ring sector 14, a light impermeable point (permanently transparent surface coating) 15 serving as a synchronization mark for the light beam emitted from the light source 11 to the phototransistor 12. On the flat main surface 2a there can be further ring sectors consisting of a photographic surface coating of uneven or uniform light transmission with synchronizing marks, which are arranged and designed corresponding to the ring sectors 13 and 14 and the synchronizing mark 15.

As FIG. 3 shows, the photodiode 7 is connected to an electronic gate circuit 18 which at the same time has an amplifier function. This gate circuit 18 is controlled by an electronic time delay element 17 connected downstream of the photo transistor 12 ) to the gate circuit 18 when the light beam emanating from the light source 11 is briefly interrupted by the opaque synchronization mark 15 on the flat main surface 2a to the phototransistor 12. After a fixed, always constant delay period t _m after the synchronization pulse has been emitted at output 17a, time delay element 17 also sends a measuring pulse (electrical voltage pulse) to gate circuit 18 at output \ 7b , with which the light beam emanating from the light source 6 and penetrating the sector 14 serving as the reference field hits the photodiode 7, through the gate circuit 18. The measuring pulse at the output 176, on the other hand, causes the data value of the light intensity to be faded out with which the light beam emanating from the light source 6 and the light beam penetrating the data field 13 hits the photodiode 7 through the gate circuit 18. The reference value of the light intensity present at the output 18a of the gate circuit in the form of an electrical voltage value and that at the output 18i / of the gate circuit 18 in the form of a further electrical spa Pending data values of the light intensity are divided into one another in an electrical normalization circuit 19. The quotient represents normalized data as a value of the light intensity in Fo ^r m of an electric voltage value at the output 20 of electronic normalization circuit 19 for disposal. The electronic normalization circuit 19 is conveniently an analog divider which z. B. can be formed by an Analog Devices Inc. (cf. Product Guide 1973 from Analog Devices Inc., Norwood, Mass. USA) with the type designation AD 530 marketed analog divider. The inputs of this analog divider are at the outputs 18a and Mb of the gate circuit 18. This gate circuit 18 can e.g. B. be formed by two sample and hold amplifiers 18c and 18c /, which are also marketed by Analog Diveces Inc. under the designation SHA-5. The »output« of amplifier 13c forms output 18a and the »output« of amplifier 18t / forms output 186. The »signal inw inputs of amplifiers 18c and 18 (/ are fed by photodiode 7, while the» control in «- The input of the amplifier 18c is connected to the output 17, 7 and thus to the phototransistor 12. So that the amplifier lic is triggered by this phototransistor 12. The "control in" input of the amplifier 18c / is at the output 17b of the /.citver/ delay -

element 17, ie the amplifier 18 (7 is triggered by the phototransistor 12 via the time delay device 17. This time delay element 17 can also have a monoflop module 16 marketed by Analog Divices Inc. under the type designation SN 74 123, its two monoflops 17c are connected in series. | Each monoflop 17c is assigned an RC-Clied I7e and 17c /, which determines the quasi-stationary state of the monoflop. The trigger input of one of the two monoflops 17c is connected to the phototransistor 12, which triggers the time delay element 17 during the output of the second monoflop I7c forms the output 176 of the time delay element 17, which triggers the amplifier \ $ d with a time delay compared to the amplifier 18c. DC voltages are present at the "output" outputs of the sample-and-hold amplifiers 18c and 18c Correspond to light that hits the photodiode 7 at the respective trigger time.

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the photodiode 7 striking, from the light source 6 outgoing light beam applied. The Kurventei! I corresponds to the intensity that the light beam hitting the photodiode 7 receives when it penetrates the uniformly blackened photographic surface over / uges of the ring sector 14 (reference field), while the curve part II reproduces the intensity of this light beam when it "penetrates the unevenly blackened ring sector 13 (data field). The curve parts III and IV are assigned to the ring sectors 13 and 14 corresponding further ring sectors which are also located on the main surface 2a of the disk 2, but are not shown the electronic gate circuit is present. It is in each case under the influence of the synchronizing pulse at the output 17a of the time delay ^c chaltung 17 disappears. For a given speed of the wheel 2 and thus also of the internal combustion engine disappears after the constant period of time _m t under the action of at outp ang 17b emitted measuring pulse, the light intensity at the point P \ of the curve part II is faded out and given as a data value to the output 186 of the electronic gate circuit 18. By dividing the two light intensities at the outputs 18a and 186 in the normalization circuit 19, the influence z. B. the aging of the light source 6 is eliminated on the reliability of the response, since the time constant light intensity in the curve parts I and III always a fixed value of the control variable of the device to be controlled, so z. B. d. R injected gasoline or

can be assigned to the ignition point of the internal combustion engine. If the disk 2 and thus also the crankshaft of the internal combustion engine rotates at a higher speed, for example, after the constant period I _n , the light intensity corresponding to point Pi of curve part II fades out, at lower speed the light intensity corresponding to point Pj. These light intensities can also depend on the elongation of the bulb 8. In the distribution of the blackening of the ring sector 13, the characteristic map of a control variable such as the amount of fuel injected or the ignition point of an internal combustion engine, determined for example by test measurements, can be stored as a function of two operating parameters such as the speed and the throttle valve position of the internal combustion engine. The normalized measured value present at the output 20 of the normalization circuit 19 in the form of an electrical voltage

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caused light intensity of the photodiode 7 hitting The light beam can be sent to an adjusting device (see, for example, German () ffenlegungsschrift 21 60 289) are forwarded, with which the control variable of the device to be controlled, so z. B. the injected gasoline quantity or the ignition point of the internal combustion engine, corresponding to the instantaneous Speed of the disk 2 and the current elongation; -. '% On of the piston 8, thus corresponding to the current speed and the current accelerator pedal or Throttle position of the internal combustion engine, is set.

Instead of a photographic surface coating of uneven or even light transmission An opaque surface coating can also be applied to the flat main surface 2a of the pane 2 be corresponding to the ring sectors 13 and 14 of FIG. 2 is divided and the one in the Ring sector 14 corresponding sector uniformly distributed bushings of the same cross-section and in a sector corresponding to the ring sector 13 uniformly or unevenly distributed bushings has different cross-sections, in which the light beam emitted by the light source on the bulb 8 Attached reading device goes out, passes through to the light-sensitive element of this reading device. The light-sensitive element of the reading device can also be arranged so that it is exposed to the light beam is hit, which is reflected in the bushings (see also DF.-OS 24 58 905 »Optical analog read-only memory«).

1 sheet of drawings

Claims (1)

Patent origin: Optical analog read-only memory with a data carrier (2) and a reading device which has a light-sensitive element (7), in particular a photodiode, and a light source (6) which emits a light beam that hits the light-sensitive element (7), which is a control variable a device to be controlled such. B. the ignition time ι ο point or the duration of the fuel supply of an internal combustion engine and can be influenced on the way from the light source (6) to the light-sensitive element (7) from the data carrier (2), the data carrier (2) compared to the ΐί reading device executes a relative movement at a continuous speed, which is an operating parameter of the device to be controlled such. B. is assigned to the rotation time of the internal combustion engine and which is in control dependent on this operating parameter and furthermore a device (18) is provided which can be influenced by a synchronization mark (15) located on the data carrier, and in which there is still a further relative movement between the Reading device and the data carrier (2) can be carried out whose. Direction deviates from the direction of the continuous relative movement, and the elongation of a further operating parameter of the device to be controlled such. B. the gas pedal or throttle position of the internal combustion engine, characterized in that the data carrier (2) influences the intensity of the light source (6) in a manner known per se as a function of the control variable that oTe device (18) after a by a time delay element (17) fixed delay period ft _m ) after being influenced by the synchronization mark (15) measures the intensity that the light beam that hits the light-sensitive element (7) at the end of this delay period (t _m ) has that a Standardization device is provided which can be actuated under the influence of the synchronization mark (15) on the data carrier (2) so that the standardization device measures the intensity of the light beam emanating from the light source (6) of the reading device when actuated under the influence of the synchronization mark (15) , which by a reference point (14), which is a fixed predetermined geometric distance from the synchronization mark (15), the data carrier (2) is effected and that the normalization device assigns this measured intensity to a fixed predetermined value of the control variable and the measured value of the intensity of the light beam striking the light-sensitive element (7) at the end of the delay period (t _m ) normalized with the measured value of the intensity of the light beam caused by the reference point (14) on the data carrier (2). The invention relates to an optical analog read-only value memory according to the preamble of the patent claim. Such read-only memories are known from DE-OS 2125 959. The disk of the known Read-only memory consists of an opaque pane with windows. If the photosensitive Being hit by a beam of light through the window creates an exciting current for an element Generated electromagnet, which influences the injection process of an internal combustion engine Duration of the light radiation emanating from the light source measured, with the difficulty can occur. For example, hatred of aging Light source the reliability of the response can be impaired. The object of the invention is therefore to provide an optical analog read-only memory of the type mentioned at the beginning specify in which the influence of the light source on the reliability of the response is eliminated. This object is achieved according to the invention with the characterizing parts of the patent claim. With the read-only memory according to the invention, the advantage is achieved that the temporally constant light intensity is always assigned to a fixed predetermined value of the control variable of the device to be controlled, so that the influence of the light source on the reliability is eliminated. It is known from DE-OS 19 49 725 that the data carrier measures the intensity of the light source in Depending on the control variable is influenced, however there is a torque transmitter to drive the data carrier provided, which works on the principle of the moving coil instrument. The torque transmitter developed when moving the data carrier tore from one rash to another a considerable inertia, under which the Control accuracy suffers. In contrast, the read-only memory according to the invention is characterized a significantly reduced inertia of the data carrier. The invention and further advantages are explained in more detail using an exemplary embodiment. 1 shows a side view of a schematically illustrated i'.nalog read-only memory according to the invention. F i g. FIG. 2 shows a plan view of the data carrier of the analog read-only memory according to FIG. 3 shows schematically an electronic evaluation circuit for the analog read-only memory according to Fig. I. F i g. 4 shows the course of the intensity of the light-sensitive element of the plotted against time Analog read-only memory according to Fig. 1 striking light beam. The data carrier of the optical analog read-only memory according to FIG. I consists of a circular disk ">. Made of translucent material, e.g. glass. This disk 2 sits in its center on a drive shaft 3 which is perpendicular to the two flat main surfaces (flat sides) 2a and 2b of disk 2. The Drive shaft 3 is rotatably mounted in a cylindrical bearing body 4 which is attached to a carrier body 5. A reading device for the data stored on the glass pane 2 has a light source 6 and a light-sensitive element, e.g. B. a photodiode 7 on. The glass pane 2 is located between the light source 6 and the photodiode 7, so that the light beam sent from the light source 6 to the photodiode 7 and perpendicular to the flat main surfaces 2a and 2b of the glass pane must penetrate the glass pane 2 and its intensity from the glass pane 2 influenced