DE1299037B - Method for reading out a detector matrix - Google Patents

Description

remain. The detector elements are in one matrix-like arrangement summarized, so that one of its entirety as a detector matrix speaks.

A block diagram of an associative memory is shown in FIG. The memory block itself is designated in Fig. 1 with 1, it has inputs for the word driver stages 2 and the places

should, whether there is a stored word at all, io corresponds to the state 0. When querying this that is the same as the word used for the query. The elements go to the L state it is correct how many such association objects are transferred to the state Z, the elements in the Zuden are, like any of these association status 0, but retain this. The query of the Objects is and, if applicable, how and where all the results contained in such a detector matrix are Association objects can be found. It is then designed as follows: In one Orders are known in which each address of the first readout, which detects all detector elements in the same associative memory as a detector element, are those in the L state net is. Detector elements are transferred to state Z by the associative interrogation process the detector elements, the word of which results in the interrogation and read signals in the rows and columns, conditions corresponds to, assigned with an L, while ao through which the respective rows and columns add Elements of the uninvolved words in the state 0 are placed in the state L ordered display elements will. Detector elements that were in state 0 before the readout do not experience any Change of state, and accordingly no read signals are generated by these detector elements, those for a display in the display elements connected to the rows and columns of the detector matrix could lead. However, the display in the column and row display elements is deceptive

Driver stages 3 via which the association subjects contained in a register 4 with regard to some detector elements are supplied. transition from the L-state to the Z-state.
The outputs of the memory block 1 are with the In a second readout is therefore with the

Detector matrix 6 connected, possibly known methods using coincidence amplifier 5 can be interposed. methods checked, which of the detector elements, which are The above-described type of reading the Er- 35 in rows or columns, the display elements result of an associative query of the memory by the first query in the L state has the advantage that one without further ado, really exist in state Z, so that conventional storage elements such as ferrite which cores due to the ambiguity of the first display or transfluxors get by. The disadvantage of incorrectly displayed detector elements which are discarded in the method is that there are difficulties with the O-state. Im kicking when there are multiple associations. In the worst case, with the known method, special precautions must then be taken for the passage when a diagonal of the detector guide of the second readout process is hit matrix passing detector elements in state L den, with which the in the detector elements of or after the Contains query in state Z, address information contained in the detector matrix comes about 45. In the case of a detector matrix of η · η detector elements, the association objects determined in the memory block result in a number of η (n-l) false displays. They will. The usual coincidence methods are required for the number of query results contained in the matrix, which is then unusable in the second readout process in the detector, if more than one detector element in the detector readout steps is still very large and the matrix is assigned an L , since then the Option 50 requires an unnecessarily large amount of time,
exists that the display is no longer unambiguous. The object of the invention was therefore to provide a readout

This will be explained briefly with reference to FIG. In this figure is a schematic for the core arrangement shown in a detector matrix, with four cores highlighted, of those in the chosen one For example, it is assumed that it is assigned an L. are. Simultaneous interrogation of all cores in all rows and columns of the detector matrix would then only show that from above or

Calculated on the left in the third, sixth and eighth 60, the marked detector elements are then separated or in the third, fourth and tenth columns of the matrix individually and one after the other.

to develop a method for such a detector matrix that has a much higher readout speed enables.

According to the invention, this object is achieved in that in a first for all detector elements of the matrix, only the display elements connected to the columns of the matrix can be read out at the same time are kept operational and that

marked nuclei, i.e. nuclei in the L-state, are present. At which of the crossing points of columns and rows are the kernels really however, cannot be clearly identified.

It is already known that an unambiguous statement can be made by one line by line and column by column separately one after the other

others are queried in a second readout, and in each case those associated with the rows of the matrix Display elements are kept operational. The operation of the method according to the invention is explained in more detail with reference to FIGS. 2 and 3. For the sake of simplicity, let me begin assumed that the detector elements of the detection

3 4

gate matrix can be read out non-destructively, so that they (e.g. a flip-flop), from the state of which one can freely choose can often be queried without knowing whether there are still marked elements in the their condition changes. It should be noted, however, that a detector matrix is present, that the method according to the invention does not affect the There is still a switching group 12 provided, the

The use of such detector elements is limited to 5 which can connect through the crevice lines. It suffices because the method according to the invention works on all lines with an interrogation pulse only with two readings, without further ado. The decoding device 11 receives transfluxors with only three stable states. Instead of both of the lines and of the network 10 or 9 assigned to each detector element column, however, on a network 10 or 9 assigned by two simple bistable elements, such as, for. B. io single line from η existing a one L be ferrite ring cores, realize the with K and K ' significant potential supplied. This information will be net. With each marking of a matrix element in the usual way, e.g. B. with diode circuits in the detector matrix (with an associative memory a more useful address, e.g. in the dual system, this is done when a word meets the conditions of the converted. Usually, such a single associative query is sufficient and a signal to the 15 directions in principle emits from a number of parallel detector matrix) then two cooperating AND circuits must then, so that these decoder cores K and K 'associated with the decoding require little time in addition.

stand L. At the first readout, the timing of the processes after the entry

the entire detector array with its Detek- write the L in the detection nuclei is now folgentorelementen detected, then only the nuclei K 'ao of: circuit 12 connects the column read lines read out while the subsequent column, and outputs to all of the lines a Interrogation pulse, wise read out the cores K are available, the read information resulting in the column read lines during the first read-out untouched signals reach the column display register 8 and remains. put all flip-flops on L, their assigned

For the description of the exemplary embodiment, 25 columns of L-cores are included. Meanwhile they are blocked by a marking, for example by an output of the line flip-flops, query result of the associative query of an associ-Subsequently, through the network 9, the first

ciative memory, assumed that the in F i g. 2 switches SA inserted from the left in the row of columns, shown distribution of marked detector whose associated flip-flop contains an L, and elements, i.e. detector 30 in the L state, has led a column interrogation pulse from the generator GS , in which the Crossing points can reach this column. Meanwhile, the third column with the eighth row, the fourth the column interrogation lines at the point of the switching column with the third and sixth rows and the device 12 are interrupted, the inputs of the row flip-tenth column with the eighth row each have a detector flop however open. All detector cores that have an element in the L state on Z. 35 stand, so make the corresponding line flip

In the first readout, which detects all detector flops on L. The network elements of the matrix arranged downstream of the rows are selected according to the invention from these written flip-flops such as only those connected to the columns of the matrix and the first in the row its display elements kept operational. The potential of the decoding device 11 increases. a display appears in the third, fourth and 40th As soon as the decoding of the column and the tenth column or in the associated display line information is finished, an element. The final impulse is the first through the network 10 in FIG. 3 shows a block diagram for a raised flip-flop brought into the state 0, which is used to carry out the invention. Are still more row flip-flops with L according to the method can serve. The detection 45 occupies, so the reading goes into the decoder matrix 6 consists of five columns and five devices 11 in the same way until all the row flip rows and each row and each column is a flop at 0. Then the network 10 outputs a display element in the form of the display registers 7 associated with the corresponding potential to the column display or 8, which are composed of flip-flops from register 8, which are connected to the network. 50 werk 9 deletes the first flip-flop marked with an L. With 9 and 10 are networks of logical switching This inevitably refers to the network 9, with the help of which only one next occupied column is highlighted, etc. If L information in the display element group 8 all column flip-flops are deleted, so all L-cores or 7 and preferably the first L in a row of the detector matrix 6 are read out, and the network 9 (row or column) is switched through. Examples 55 can have a certain potential at the output Hef for such networks are shown in FIGS. 4, 5, 6, indicating the end of the operation, for the logical network 9 in A possible embodiment for the sub-shell fig. 4 and for the network 10 in FIG. 5 from the display register 8, the network 9 and out. the switching group 12 is shown in FIG. 4 shown.

In the block diagram of FIG. 3 are the 60 The switching group 12 consists of the upper network 9 for the columns still switch SA after the third of the circuit diagram and includes the and-ordered, which are controlled by it. The off circuits SE and the generator GSR. The flip-flops FF and the decoding device 11 belong to the corridors of the network 10 for the lines going to the display register 8. Another output AND circuits connected to their input. of the network 10 leads to the display register 8. The 65 The network 9 is also implemented through the flip-flops FF outputs of the network 9 to the deco-subordinate AND circuits. The converting device 11, and a further output binding of the network 9 with the columns takes place via the switch SA, whose second input connects to the display device, not shown here

Reading out the columns regulating generator GS is connected. The switches SA are also in principle AND circuits, but because of the larger read currents it may be necessary under certain circumstances to use special high-current coincidence circuits for this.

5 shows an example of the realization of the indication register 7, and the network 10, and in Fig. 6, a second variant for a combination of AND circuits is shown, which allows highlighting of a set of L, the first L. The display register 7 consists of the flip-flops FF ' and the AND circuits connected upstream of their inputs, the network 10 is implemented by AND circuits linked to one another.

Since the decoding in clocked systems requires a defined time, the first L flip-flop FF 'can also be erased with delayed signals, as shown in FIG. 5 the delay lines τ are used in coincidence with a clock pulse. Similar indexing means are also shown in FIG. 6 to think about.

In the exemplary embodiment, detector elements are assumed to have at least three stable Have states, that is to say a first change of state in the case of the marking itself and two more in the case of can experience the two readings. The application of the readout method according to the invention however, it is not restricted to detector matrices constructed from such elements. Rather can it also applies to detector elements with only two stable states, e.g. B. the usual ferrite ring cores, to be used. It is only necessary to do the first reading, which is for all detector elements at the same time takes place in such a way with the marking to couple the expression of the associative query itself, that the display elements connected to the columns of the detector matrix are already present in the latter keeps operational, so that the L-marking of the detector elements and the one with the columns connected display elements takes place at the same time, so it is only the second column-by-column reading required to get the query result.

In addition to the possibility of building the detector matrix from the simplest and therefore cheapest elements this variant of the method according to the invention offers the further advantage of a special one time-saving process.

Claims (1)

Claim: A method for reading out the display result contained in a detector array using a display arrangement which includes a respective display element per column and row of the matrix, characterized in that at '- only associated with a first simultaneous for all detector elements of the array readout with the columns of the matrix Display elements are kept ready for operation and that then the columns of the matrix containing the marked detector elements are interrogated individually and one after the other in a second readout and the display elements connected to the rows of the matrix are kept ready for operation in each case. For this purpose 2 sheets of drawings