This application claims priority to European patent application Ser. No. 13 165 141.6, filed Apr. 24, 2013, the entire contents of which is incorporated herein by reference.
The subject matter disclosed herein relates generally to light curtains and, more specifically, to safety light curtains for monitoring a protective field and to such light curtains which comprise optoelectronic components interconnected by a communication bus. Furthermore, the present invention relates to optical units which are part of such a light curtain and to a method for allocating individual addresses to each of a plurality of optoelectronic components.
Generally, light curtains and in particular safety light curtains detect the movement or intrusion of objects into guarded zones, and more particularly, provide protection for human operators who are working with machines or other industrial equipment.
Light curtains employing infrared or visible light beams are used to provide operator safety in a variety of industrial applications. Light curtains typically are employed for operator protection around machinery, such as punch presses, brakes, molding machines, automatic assembly equipment coil winding machinery, robot operation, casting operations and the like. Conventional light curtains typically employ light emitting diodes (LED) mounted at spaced positions along a transmitter bar at one side of the guard zone and phototransistors (PT), photodiodes or photoreceivers mounted along a receiver bar at the opposite side of the zone. The LEDs transmit modulated infrared light beams along separate parallel channels to the PTs at the receiver bar. If one or more beams are blocked from penetration by an opaque object, such as the operator's arm, a control circuit shuts the machine down, prevents the machine from cycling, or otherwise safeguards the area.
Usually, safety light curtains comprise two optical units (also called bars, sticks, edges or strips), which are formed as two different constructional units, one of the optical units having the functionality of an emitter and one of a receiver. This dedicated architecture of an emitter and receiver, however, has several drawbacks.
Firstly, the fabrication costs are high, because each type of optical unit has to be fabricated differently. Further, it is known to use the optical path from the emitter to the receiver also for transmitting information, for instance for a synchronization. However, in a system where one of the optical units has only the function of an emitter and the other one only the function of a receiver, the optical communication is only unidirectional, i.e. from the sender side to the receiver side. Therefore the optical synchronization may be difficult and a transmission of communication information is possible only in one direction.
It has already been proposed to locate receivers and transmitters on each of the first and second optical units, as this is described in the European patent EP 1870734 B1. Here, the grid has two identical transmitting/receiving strips, to which transmitting and receiving units are fixed. The transmitting/receiving strips are placed opposite to each other with a protective field being formed between the strips. The transmitting/receiving strips are identically formed in control and evaluation units. The control and evaluation units have safety outputs, which are formed together as a switching channel. An identical power supply is provided for all the strips.
Furthermore, it is known from EP 2511737 A1 to provide a modular light curtain and optical unit for such a light curtain.
Whenever electronic components are interconnected by means of communication bus, it is necessary that each of the components has a clearly distinguishable individual address which is also known to the controller for providing data intended for the particular electronic component in the downlink and for distinguishing between the data sent by a particular component in the uplink. When assembling light curtains containing a plurality of optoelectronic components each may be provided with a particular address which is stored in the controller and the optoelectronic component itself, so that the communication can take place. The address value is normally pre-defined and correlated with a particular function within the bus system and such a pre-defined address allocation has the disadvantage that this particular function of a component within the bus has to be known before assembly. In the case of light curtains having optoelectronic components with sender and/or receiver elements this means that during assembly each optoelectronic component has to be mounted in a pre-defined assembly location corresponding to its address.
Thus, it would be desirable to provide a light curtain and a method for allocating an individual address to each of a plurality of optoelectronic components, which reduces the expenditure during assembly and also complies with the requirements for a design for testability and maintenance.
The subject matter disclosed herein describes a method for allocating an individual address to each of a plurality of optoelectronic components in a light curtain, which reduces the expenditure during assembly and also complies with the requirements for a design for testability and maintenance.
The present invention is based on the idea that the optoelectronic components are not provided with a pre-set address by the manufacturer, but are allocated their address depending on a geometric position of the respective optoelectronic component with respect to other optoelectronic components within a light curtain. In particular, setting up a light curtain for the first time may initiate an address distribution by daisy chain addressing and the optoelectronic modules are connected to each other for the address distribution in a serial interconnection scheme. By such a dynamic on-site address allocation a much higher flexibility and an improved adaptation to particular data structures which are necessary on-site during operation, is feasible. Furthermore, retrofitting and repair of the light curtain system is facilitated. Using a daisy chain addressing allows an easy correlation of the geometric position of the optoelectronic components in respect to each other, if they are aligned in some linear configuration. For covering matrix-shaped arrays, a meandering daisy chain address line can be used for allocating the addresses of the individual optoelectronic components.
The address allocation according to the present invention can be used to full capacity by employing it together with a light curtain having emitters emitting infrared radiation (with a wavelength between 750 nm and 1500 nm) or visible light (having wavelength between 400 nm and 750 nm).
According to the present invention, each of the optoelectronic components comprises an electronic circuit for driving the at least one light-emitting element and for processing signals generated by the at least one light-receiving element. This arrangement has the advantage of providing a highly modular setup and allows for a highly flexible and cost-effective assembly of the optical unit and resulting light curtains.
For storing the allocated address, the optoelectronic components each comprise a permanent or volatile memory. If the storing means permanently stores the allocated addresses, the address allocation procedure only has to be performed when a setup of the light curtain is initialized. This may be the case for the first installation, but also when re-arranging the optical units or after maintenance works. However, the address may also be stored in a volatile memory and always be newly allocated during the power-up process. The optical units according to the present invention may either be combined with just a reflective surface or with at least one second optical unit of the same kind to form a light curtain for monitoring a protective field.
The present invention furthermore relates to a method for allocating an individual address to each of a plurality of optoelectronic components connected to each other via a communication bus. According to this method, a control unit broadcasts a request to all optoelectronic components within the setup in a first communication direction. Each of the optoelectronic components then transmits an individual response in a second communication direction. Depending on the position of the respective optoelectronic component with respect to the other optoelectronic components, an individual address is allocated to each of them. This method of assigning individual and unique addresses to the optoelectronic components allows for a high flexibility and cost-effective setup of the complete system.
According to the present invention, at least the signal line that is used as an address line is formed as a serial connection in order to provide a daisy chain addressing scheme. The daisy chaining allows for a particularly simple determination of the positions of the optoelectronic components with respect to each other. In addition to the addressing connection, the controller may also have the possibility to access every single optoelectronic component randomly by means of a data bus with a node address. There are at least two options because the bus connection and the daisy chain do not necessarily have to be formed by the same structure. The bus system may have three lines, in particular clock, data-in and data-out, and one of them forms the daisy chain. In particular, either the data-in line or the data-out line is a serial connection and the others are parallel. On the other hand, the bus system may also have three lines (clock, data-in and data-out) and an additional daisy chain connection is provided for distributing the addresses which does not form part of the bus connection, but is only used during setup for an address distribution.
Serial connections generally have an impact on signals passed along them in that the signal gets delayed compared to those signals that do not pass through the daisy chained component, e.g. a clock signal. In order to allow for a defined re-synchronization with those signals that are transmitted bypassing the serial connection, the system may comprise one or more delay elements for delaying, signals transmitted on said serial interconnection. These delay elements can provide a buffer function and allow for a re-synchronization of the daisy chained signal with e.g. the clock signal.
For allocating the individual address depending on the position of the optoelectronic components in respect to each other, there are mainly two possible procedures. Firstly, the address is given by the controller as a new data word and stored in the memory of the optoelectronic component.
Alternatively, also an already present unique identifier of the optoelectronic component can be read out and can be assigned the meaning of a particular address, depending on the position of the respective optoelectronic component. For this procedure, during the startup, an individual and unique identifier of each optoelectronic component is read out and set into relation with the physical position in the bus. This relation is stored in the control unit, again either permanently or volatile. There are different options for this individual and unique identifier. In particular, a unique identifier may be given during semiconductor fabrication and assembly of the optoelectronic component. Alternatively, the unique identifier may also be assigned during the module production in the production site or during the light curtain production in a configuration cell or at the OEM customer's premises. In any case, no manipulation of the stored data in the memory of the optoelectronic components has to be performed, but still the identifier stored within the optoelectronic component does not in itself have to contain the meaning and information of a particular address.
Due to safety reasons, for answers from the optoelectronic component to the microcontroller, the inverted node address can be used as a node identifier. The result is that the microcontroller communicates to each of the optoelectronic components using their unique node address, whereas when the optoelectronic components need to transmit data to the microcontroller, the node identifier. i.e. the inverted node address, is used.
These and other advantages and features of the invention will become apparent to those skilled in the art from the detailed description and the accompanying drawings. It should be understood, however, that the detailed description and accompanying drawings, while indicating preferred embodiments of the present invention, are given by way of illustration and not of limitation. Many changes and modifications may be made within the scope of the present invention without departing from the spirit thereof, and the invention includes all such modifications.
Various exemplary embodiments of the subject matter disclosed herein are illustrated in the accompanying drawings in which like reference numerals represent like parts throughout, and in which:
In describing the various embodiments of the invention which are illustrated in the drawings, specific terminology will be resorted to for the sake of clarity. However, it is not intended that the invention be limited to the specific terms so selected and it is understood that each specific term includes all technical equivalents which operate in a similar manner to accomplish a similar purpose. For example, the word “connected.” “attached.” or terms similar thereto are often used. They are not limited to direct connection but include connection through other elements where such connection is recognized as being equivalent by those skilled in the art.
Referring now to
The light curtain 100 in this embodiment consists of two identical first and second optical units 102, 104, which form between each other a plurality of light barriers for monitoring a protective field. However, the ideas of the present invention are also applicable to arrangements, where only one optical unit 102 is used together with a reflective opposing surface or in systems which comprise more than two optical units. The optical units 102, 104 may for instance be formed according to the principles of the European patent application EP 2511737 A1, and may in particular use plug-in modules 106, 108 for defining their respective functionality.
According to the embodiment shown in
Each of the optical modules 110 comprises a plurality of optoelectronic components with their associated circuitry for emitting and sensing the radiation beams. The second optical module 112 contains the same optical functions and additionally, at least one microcontroller and optionally electronic circuitry, such as an interface with an external connector. However, for using an addressing according to the present invention, the optoelectronic components do not necessarily have to be grouped in optical modules 110, 112.
A more detailed view of a part of two opposing optical modules 110 is given with reference to
The radiation beams 114 may for instance be activated sequentially, one beam at a time, from one peripheral end to the other peripheral end of each stick. Because each optical unit 102, 104 has transmitting and sensing photo elements, the scan through the light curtain activates every element sequentially and with an alternating direction, the beam being sent from the second optical unit 104 to the first optical unit 102 and back again. During such a scan sequence, the respective receiving stick always only sequentially detects the light from the pre-determined emitting element to the corresponding receiving element. In order to allow for such a complex scan procedure, each optical unit 102, 104 is formed by a plurality of optoelectronic components 116 each comprising at least one light-emitting element 118 and at least one light-receiving element 120.
Each of the optoelectronic components 116 has a rather high degree of integrated intelligence in the form of a separate control element 122 which may for instance be formed as an integrated circuit, such as an application specific integrated circuit (ASIC). Each of the control elements 122 provides electronic circuitry for driving the at least one light-emitting element 118 and for processing signals generated by the at least one light-receiving element 120. In order to communicate with the higher level controller, each of the optoelectronic components 116 is connected to a communication bus 124.
Alternative architectures which can also be advantageously used with the addressing scheme according to the present invention are depicted in
In order to provide the complex control scheme to each of the optoelectronic components 116, it is required that they have an individual address which is also indicative of their position within the light curtain 100. According to the present invention, this is achieved by allocating the addresses after assembling and interconnecting the optoelectronic components 116 to form an optical unit 102, 104.
The data transmission line (data-out) is configured as a single bit unidirectional connection from the microcontroller to the control elements 122. In particular, the data-out line is a shared communication line out of the microcontroller to all of the control elements 122. In other words, all control elements 122 are connected in parallel and the transmission line is buffered on each module if the plurality of optoelectronic components is grouped together in optical modules 110.
The data-in line 130 is another single bit unidirectional line for receiving data which is sent from the control elements 122 to the master. According to the embodiment shown in
Generally, every communication is initiated by the microcontroller which acts as the bus master. A particular control element 122 may only transmit information onto the data-in line 130 after a request originated by the microcontroller has been recognized and validated. The response onto the data-in line 130 must then follow the particular bus protocol. Moreover, the communication line from the control elements 122 to the microcontroller is a point-to-point communication bus which is synchronous to the single global system clock. That means that each control element 122 takes information from the previous control element and forwards the merged results of that data and its internal data to the next control element. With a configurable option to register the data in a flip flop and send it on the following clock.
Each control element 122 is connected to a single power line (V+) which may for instance be a 12 V to 15 V power line. The control element 122 may also comprise internal power management blocks for regulating its own power supply.
The main functions of the optoelectronic component 116 lie in sensing and emitting pulsed radiation in a controlled manner under the supervision of a microcontroller.
The photodiode D1 senses radiation, and in particular light, coming from the opposing optical unit and generates an analog input signal which is connected to a receiving amplifier integrated into the control element 122. For a person skilled in the art, it is understood that also more than one photodiode can be provided.
Furthermore, the control element 122 controls an LED drive circuit so that the LED D2 emits a radiation beam to the opposing optical unit. The drive circuit is controlled by the control element 122 in a way that the emitted light intensity has a specified level. Also, more than one light-emitting diode D2 may be provided in the circuit according to
For instance, according to a typical implementation, an optical module 110 may have eight or nine optoelectronic components 116.
For regulating the driver transistor T1 of the diode D2 a sensing input is provided for sensing the emitted current of the light emitting diode D2.
The control element 112 has analog and digital sections as well as interfacing cells. The analog amplifier 134 is operable to detect the signals measured by the photodiode. Furthermore, the logic section 132 contains the registers which are used for storing the address of the particular control element 122. The clock 140 is used to synchronize all control elements with the microcontroller, run the internal logic, and sample the communication bus starter lines. The internal LED control 138 controls the LED current value by measuring the voltage across the external resistor R1 shown in
The power supply block 136 generates the voltage for supplying the internal circuitry, such as the digital logic supply and the analog supply. Auxiliary voltages for the bias of the photodiode and the analog ground reference may also be generated here.
The communication block 142 interfaces on one side with the external microcontroller serial bus 124, as shown in
With respect to
In order to allow that the ASICs are operated in such a multiple ASIC system, each ASIC is assigned a unique identifying address which is stored in a bank of registers, and the ASICs respond to system commands via a shared serial bus. In response to the commands, the ASIC replies via a shared single-bit serial bus with an arbitration mechanism.
Furthermore, the plurality of ASICs is interconnected by means of at least one serial daisy chain line which in the embodiment shown in
Based on the arrangement shown in
During normal operation, the microcontroller which is present in the controller module 112, but not shown in detail in the figures, addresses each ASIC by inserting its corresponding node address into the command packet. Each ASIC is identified by its address which is loaded into the node address registers. Due to safety reasons, for answers from the ASIC 122 to the microcontroller 112, the ASIC uses the inverted node address, which will be called node identifier in the following. Hence, during normal operation the microcontroller will communicate with each ASIC using its unique node address and when the ASIC needs to transmit data to the microcontroller, the ASIC uses the node identifier. According to one particular embodiment, the ASIC farthest away from the microcontroller has the highest priority. However, this is only a question of definition and any of the other ASICs 122 may also be chosen to have highest priority.
A broadcast command can be sent with the broadcast address and all connected ASICs will execute the broadcast command. The ASICs will respond with their unique node identifier and the ASIC with the highest priority will win an arbitration phase and the microcontroller only receives the answer from this ASIC. The highest priority is defined by the position on the bus.
Referring now to
For setting the first address (see
After a pre-determined time span, the microcontroller sends another set address command on the data-out line 128. In this case, ASIC number 1.3 detects a high level on its TXAI pin and will store the address “3” in its node address registers. The microcontroller will now set the ASIC configuration bits to above a function with no pull-up. This will allow the TXAO pin to drive high. After the ASIC number 1.3 has stored the address, the ASIC will drive its TXAO pin high. The ASIC now has a valid address and the TXAI pin is in idle mode. Now the ASIC number 1.3 has left the start-up mode and is idle, waiting for commands, as is symbolized in
The ASIC number 1.4 will always ignore this and any subsequent set address command, because it is no longer in the address mode.
The final set is shown in
The addressing procedure is illustrated in
The addressing mode logic 145 of the last ASIC 122 now sets the address field 146 to a value different from the broadcast address. The fact that the addressing mode logic now has an address different from the broadcast address in the address field 146, leads to an output signal of logical “1” at TXAO, which in turn is passed on to the input TXAI of the next following ASIC 122, allowing this ASIC to take the next set address command. Accordingly, the enable for the set address command is passed from ASIC to ASIC from the end of the daisy chain path to the microcontroller. In the course of this addressing each of the control elements 122 gets its address set according to its position within the sequential row of control elements 122. Each of the control elements 122 in their turn accept the set address command, set their address accordingly and propagate the address enable to the next following control element 122.
ASIC m.2 equally does not find an enable signal and only the last ASIC m.3 has the enable signal and therefore the address is saved.
During the next clock period the next set address command is sent out and received. In this case, again, ASIC m.1 does not detect an enable and therefore does not save an address. ASIC number m.2 has the enable and saves the address. On the other hand, ASIC m.3 has already been addressed and therefore does not save an address.
In the last step, ASIC m.1 has already received the enable from ASIC m.2 and therefore saves the address when it receives a set address command from the microcontroller. The procedure is performed accordingly for any larger number of control elements and always starts with the last one in the serial row and finishes with the ASIC that is closest to the microcontroller.
After power-up, each ASIC completes the internal power-up sequence and then all the ASICs are ready for the address allocation procedure. Each ASIC drives its TXAO pin to a static low. Therefore, all ASICs, except the very last ASIC at the end of the series of ASICs, detect a static low at the TXAI pin. The very last ASIC, as already explained, has a static high level due to the internal pull-up resistor and due to the fact that no TXAO buffer drives it low. The microcontroller transmits the broadcast command set address to all connected ASICs. All ASICs interpret the received data. Only the very last ASIC (in the example shown in
Furthermore, a node identifier is set as a bit-wise inverted mirror of the node address. The condition of accepting the set address command is that the ASIC is in the address mode and has a high level on the TXAI pin. Once the node address and possible other data have been set, the configuration bits will be changed to a buffer function, which will cause the TXAO pin to drive high to the next ASIC, or in case of the first ASIC, to the microcontroller. After a time t NXT_CMD has lapsed, the microcontroller sends the next set address command to all ASICs requiring to set an address with a value reduced by one. In this case, the very last ASIC will refuse this and all later set address commands, regardless of what address is required to be set, because this particular ASIC is no longer in the address mode. As already mentioned, ASIC number m.2 detects its TXAI pin in a static high, which is delivered by the ASIC number m.3, and will handle the set address command accordingly.
The set address command is a broadcast command from the bus master, the microcontroller, to the ASICs. The command contains the node address, which will be stored in the ASIC in its address field and may for instance be a 9 bit node. Furthermore, according to an advantageous improvement, the inverted value of this address may also be stored in the ASIC. At start-up, each ASIC needs to have its address set. The addressing has to be in exactly the same order as the physical positions of the ASICs in their application environment. Each ASIC must be in a default reset condition, where the node address is not stored and the TXAI pin must be at a high level in order to start the addressing procedure, as already mentioned above. The ASIC stores the transmitted parameter node address at the dedicated register address of its addressing mode logic. Afterwards, the ASIC reads the register, inverts the read value, and stores it at the dedicated register address for the parameter node identifier. Finally, the ASIC reads the node identifier from the registers and compares the read value with the value from the original command. This read-verify procedure is done to ensure that no errors occurred when storing the addresses to the registers.
The use of the terms “a” and “an” and “the” and similar referents in the context of describing the invention (especially in the context of the following claims) are to be construed to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. The terms “comprising,” “having,” “including,” and “containing” are to be construed as open-ended terms (i.e., meaning “including, but not limited to,”) unless otherwise noted. Recitation of ranges of values herein are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. All methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context. The use of any and all examples, or exemplary language (e.g., “such as”) provided herein, is intended merely to better illuminate the invention and does not pose a limitation on the scope of the invention unless otherwise claimed. No language in the specification should be construed as indicating any non-claimed element as essential to the practice of the invention.
It should be understood that the invention is not limited in its application to the details of construction and arrangements of the components set forth herein. The invention is capable of other embodiments and of being practiced or carried out in various ways. Variations and modifications of the foregoing are within the scope of the present invention. It also being understood that the invention disclosed and defined herein extends to all alternative combinations of two or more of the individual features mentioned or evident from the text and/or drawings. All of these different combinations constitute various alternative aspects of the present invention. The embodiments described herein explain the best modes known for practicing the invention and will enable others skilled in the art to utilize the invention.
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13165141 | Apr 2013 | EP | regional |
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European Extended Search Report; Application No. 13165141.6; Dated Jan. 24, 2014—(11) pages. |
Number | Date | Country | |
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20140319358 A1 | Oct 2014 | US |