DE3921008A1 - RECURSIVE NOISE REDUCTION - Google Patents

Abstract

An input still video signal 12, eg reproduced from a video recorder, is digitised 14 and multiplied by a constant (1-K1, K2, ... Kn) and passed to first terminal of adder 20 and then to field memory 24 (or frame memory 46, figures 4 and 5). The field (frame) delayed signal is then multiplied by a constant K1, K2 ... Kn and supplied to second terminal of adder 20. The constants (1-K1 ... Kn) and K1 ... Kn, are changed, under the control of timing unit 30, at the end of each field (frame) period, in an example the values of K are 0, 1/2, 2/3, ... (n-1)/n to allow averaging of the input still image signal and reduction of associated random noise. The noise reduced still video signal is available at terminal 32 after D/A conversion 22. <IMAGE>

Description

The invention relates to a noise reduction or -un suppression circuit, especially a recursive Noise reduction circuit in which a field (field) of a standing (image) video signal stored and to reduce or suppress a noise signal re is added in italics.

A conventional noise reduction circuit for Un suppression of a noise contained in a video signal Signal or noise component is with a magneti and recording / playback device for recording and Play a video signal used. The noise Suppression circuit serves to suppress the noise signal contained in the video signal, e.g. in one the magnetic recording / playback device fed still image signal, and it uses a memory for storing at least one single or full stills for the recursive processing the same. Such a recursive noise sub pressure circuit is e.g. in "TELEVISION JOURNAL", 1979, Vol. 33, No. 4, "NOISE REDUCER", in "TELEVISION TECHNOLOGY ", Jan. 1987," NEC NOISE WIPER VC-D7HF "and in "TELEVISION JOURNAL", ITEJ Vol. 11, No. 13 "IMPROVE- MENT OF IMAGE BY APPLICATION OF DIGITAL MEMORY ", be wrote.

The noise suppression circuit for recursively adding a still picture for each (of each) field is constructed, for example, as follows: the still picture of a current field fed via the input terminal is multiplied by (1- K) ( K = a fixed one ) in a multiplier stage Size and 0 < K <1) multiplied and then fed to an adder whose output signal is written or read into a field memory. To the field memory is a handle by means of a timing generator Herge manufactures to generate various timing signals (timing signals) in synchronism with the still image fed to the input terminal. The output signal added by the adding stage, which has been obtained for the immediately preceding field, is read from the field memory. The read out added output signal is multiplied by K by a coefficient multiplication stage and then in turn fed to the ad dation stage.

The operation described is repeated leads, as often as a still picture signal of a new field is applied to the input terminal so that at the off a video signal with reduced or under pressed interference signal or noise component obtained who that can.

Another type of recursive noise reduction circuit with two adders has also been used. In this noise suppression circuit, a still picture of an instantaneous field (field) supplied by the input terminal is fed to first and second adder stages and a timing generator circuit, the output signal being fed from the first adder stage to the output terminal and simultaneously being written into a field memory, to which a Accessed by the timing generator circuit; the added output signal obtained in the immediately preceding field from the first adding stage is read out from the field memory and fed to the second adding stage. The output signal from the second adder is multiplied by a multiplier by K (0 < K <1) and then fed to the first adder whose output signal as an added output signal of a signal equal to (1 K) times the still image signal of the instant or present field and a signal equal to K times the added output signal of the immediately preceding field is obtained or obtained.

In the conventional recursive noise suppression circuit described, a still image signal appearing at the end of the recursive addition operation is obtained or taken off at the output terminal. In this case, SI _n and SO _n denote an input still image signal and an output still image signal of the n th field, if n = 0 applies to the present field:

SO ₀ = (1- K) · SI ₀ + (1- K) · K · SI _-1 + (1- K) · K ² · SI _-2 + (1- K) · K ^{(n -1)} · SI _{- (n -1)}
= (1- K) · (SI ₀ + K · SI _-1 + K ² · SI _-2 + K ^{(n- 1)} · SI _{- (n -1)} ) (1)

Here is the field correlation of the input still image signals "1" so that the following equation is obtained becomes:

SI _-n = SI _{- (n + 1)} = SI (2)

As a result, equation (1) can be rewritten as follows will:  

The noise or noise component can be like express as follows:

NO ₀² = (1- K) ² · NI ₀² + (1- K) ² · K ² · NI _-1 ² + (1- K) ² · K ^{(n -1)} · NI ² _{- (n -1)}
= (1- K) ² · NI ₀² + K ² · N _-1 ² + K ^{(n -1)} · NI ² _{- (n -1)} (4)

Here, NI _{- n} and NO _{- n} denote an input interference signal and an output interference signal, respectively, which is obtained before n fields in the case that n = 0 applies to the present (current) field.

In this case, the input interference signal NI norma no field correlation. The amplitudes however, the level remains constant over time; then the following equation can be derived or based on be put because its potency (power) constant is:

NI _{- n} ² = NI _{- (n +1) ²} = NI ² (5)

By summarizing equations (4) and (5) he keep the following equation:

The following equation can be derived from equation (6):

As described above, from a comparison of equations (3) and (7), it is clear that the output still image signal SO is set to the same level as the input still image signal SI , while the level of the output noise signal NO is multiplied of the level of the input interference signal NI is suppressed. In this case, the noise reduction effect can be further improved if the size of K approaches "1".

However, as is clear from equation (4), in the described noise suppression circuit, the final addition coefficient for the input noise NI is different in each field, and the addition size becomes larger in a field closer to the present field. Therefore, if the number of added fields is small (if the noise signal is suppressed by using 5 or 10 fields, for example), a substantial or notable noise reduction effect cannot be obtained.

To solve this problem it could be thought instead of the recursive noise reduction circuit using a noise reduction circuit a field memory for the still image signal of each To use the drawing file.

In this case, a still picture signal fed in via the input terminal is fed to the timing generator circuit and to a number of field memories. The partial image memories in a number ( s ) to be added together are used for storing the still image signals of n partial images. If access to the sub-picture memories is made by the clock generation circuit, the still picture signals stored in the sub-picture memories are multiplied by a coefficient multiplier by l / n corresponding to the number of sub-picture memories and then fed to an adder. An output still image signal from the adding stage is output at the output terminal.

The output still image signal SO and the output interference signal NO are fed in accordance with (following) equations (8) and (9):

If - as described - the noise suppression circuit different from the recursive noise suppression circuit is used, the final addition coefficient for the input interference signal NI can be set the same in each field, as is clearly evident from equation (9). The input noise signal NI in each field therefore contributes to the noise reduction by the same amount. As a result, a sufficiently large noise reduction effect can be obtained even when the number n of the sub-images is small.

In this case, however, n field memories are necessary for the n addition fields (adding fields), so that the noise suppression circuit has large dimensions.

For this reason, there has been a need for a long time a recursive noise reduction circuit that has small dimensions (is compact) and a considerable noise reduction effect even then is able to guarantee if the number of additions drawing files or added drawing files is small.

The object of the invention is therefore to create a re italic noise reduction circuit, which is also in In the case of a small number of addition fields, one considerable or significant noise reduction too guarantee and with which it is for the achievement a sufficiently large noise reduction effect it is not necessary to include sub-picture memories in a number speaking to provide the addition drawing files.

The invention relates to a recursive noise sub press circuit for storing a still video i gnals of at least one partial image (field) and to the right Italic addition of the same for the purpose of reduction or sub  pressing the noise or noise component of the standing image video signal, comprising an A / D converter to Umwan converting the still video signal into a digital signal, an instantaneous coefficient unit for multiplication ren of the digital image converted by the A / D converter gnals with 1 / ℓ (with ℓ reception order or order of the still video signal), a recursive ad the unit for sequential and recursive adding a still video signal immediately preceding field to the input still video signal for the purpose of eliminating the Störsi contained in the latter component from that through the instantaneous coefficients ten unit with 1 / ℓ digital signal, one Field storage unit for storing the output i gnals of at least one drawing file from the recursive Adding unit, a pre-or before coefficient unit for multiplying previous (prece ding) data of the still video signal of the immediate previous, read from the field memory unit the drawing file with (ℓ-1) / ℓ for the subsequent lie Delivery of the multiplication result to the recursive ad diereinheit, a timing generator for manufacture access to the sub-image storage unit at a given time or with a given NEN timing in synchronism with the still video gnal and for delivery of a predetermined or pre set (preset) control signal to select the previous previous data of the before coefficient unit fro coefficient unit and a D / A converter for Um convert the digital signal, its interference signal component has been eliminated and that by the recursive adder unit is supplied in an analog signal.

The invention also relates to a recursive noise suppression circuit for storing a still image video signal from at least one field and for recursively adding the same to reduce or suppress the noise or interference signal component of the still image video signal, comprising an A / D converter for converting the input Still video signal into a digital signal, an instantaneous coefficient unit for multiplying current or present data of the input still video signal, output from the A / D converter, with (1- K _ℓ ) (with ℓ = reception order or order number des Stillbildvideosi gnals), a recursive adding unit for sequentially recursively adding a still image video signal of an immediately preceding field to the input still image video signal for the purpose of eliminating the interference signal component contained in the latter from the output signal from the instantaneous coefficient unit, storing a field unit for storing the output signal from at least one field (of) the recursive adding unit, a pre- or before-coefficient unit for multiplying previous data of the still video signal of the immediately preceding field, read out from the field memory unit, with K _ℓ and for subsequently supplying the multiplication result to the recursive adding unit, a timing generation unit for establishing access to the partial image storage unit at a predetermined time or with a predetermined timing (at a preset timing) in synchronism with the still video signal and for supplying a predetermined control signal for selecting the previous data and the current one (or before) data of the before coefficient unit and the instantaneous coefficient unit for the before and instantaneous coefficient unit, and a D / A converter for converting the digital signal, the interference signal component of which is eliminated has been fed and which is fed by the recursive adder into an analog signal.

The invention also relates to a noise sub press circuit for storing a still video i gnals at least one full image (frame) and to the recur sive adding it for the purpose of reduction or sub pressing the noise component of the still videoi gnals comprising an A / D converter for converting the input gangs still video signal into a digital signal, a Instantaneous coefficient unit for multiplying the digital signal converted by the A / D converter 1 / ℓ (with ℓ reception order or order number of the Still video signal), a recursive adding unit to sequential and recursive adding of a still image vi deo signals of an immediately preceding frame (frame) to the input still video signal for the purpose of removal supply of the interference signal component contained in the latter from that by means of the instantaneous coefficient unit Digital signal multiplied by 1 / ℓ, a full screen memory unit for storing the output signal from at least one frame (of) the recursive adder unit, a pre- or before-coefficient unit to multiply previous data of the still image vi deo signals of the immediately preceding frame, read from the full-frame memory unit, with (ℓ-1) / ℓ and then deliver the multiplication result nisse to the recursive adding unit, a clock generator unit for establishing full screen access storage unit at a predetermined time or at a preset timing in Synchronism with the still video signal and to lie far from a predetermined or preset tax gnals to select the previous data (from) the previous forth coefficient unit for the before coefficient unit and a D / A converter for converting the digitali gnals, whose noise signal component has been eliminated and fed by the recursive adding unit becomes an analog signal.  

The invention also relates to a noise suppression circuit for storing a still video video signal of at least one frame and for recursively adding the same in order to reduce or suppress the interference component of the still video signal, comprising an A / D converter for converting the input still video signal into a digital signal, an instantaneous coefficient unit for multiplying current data of the input still video signal, output from the A / D converter, with (1- K _ℓ ) (with ℓ = reception order or order number of the still video signal), a recursive adding unit for sequential and recursive adding a still video signal from an immediately preceding frame to the input still video signal for the purpose of removing the interference signal component contained in the latter from the output signal from the instantaneous coefficient unit, a frame storage unit for storing the output signal of at least one frame from the recursive adder unit, a pre-or before-coefficient unit for multiplying previous data of the still video signal of the immediately preceding frame, read out from the frame memory unit, with K _ℓ and for subsequently delivering the multiplication result to the recursive adder unit, a clock generation unit to access the frame storage unit at a predetermined time or at a predetermined timing in synchronism with the still video signal and to supply a predetermined control signal to select the previous data and the current (or existing) data of the before coefficient unit and Instantaneous coefficient unit for the before and instantaneous coefficient units and a D / A converter for converting the digital signal, the interference signal component of which has been eliminated and which is fed by the recursive adding unit becomes an analog signal.

The following are preferred embodiments of the Er Finding explained in more detail with reference to the drawing. It shows gene:

Fig. 1 is a block diagram of a circuit according to a first Rauschunterdrüc kung exporting approximately of the invention,

FIG. 2 is a block diagram of an exemplary timing generator circuit shown in FIG. 1;

Fig. 3 is a block diagram of a second exporting approximately of the invention,

Fig. 4 is a block diagram of a further embodiment of the invention and

Fig. 5 is a block diagram of yet another embodiment of the invention.

Fig. 1 shows a noise reduction circuit for use in, for example, a magnetic recording / playback device. In Fig. 1, 12 denotes an input terminal to which a still picture video signal previously selected or extracted sequentially is applied, which is converted into a digital signal by an analog / digital or A / D converter 14 and then coefficient circuits or -circuits 16 ₁ , 16 ₂ , ..., 16 _{n are} fed in and multiplied by them with (1- K ₁ ), (1- K ₂ ), ..., (1- K _n ). The output signals of the coefficient circuits 16 ₁ - 16 _n are selected by a switch 18 sequentially with a field frequency and then fed to an (an) adding circuit or stage 20 , the (whose) output signal of a digital / analog or D / A converter 22 supplied and at the same time is written into a field memory 24 . The output signal of the field memory 24 is fed to coefficient circles 26 ₁ , 26 ₂ , ..., 26 _n and multiplied by them for the number ( s ) of added fields with K ₁ , K ₂ , ..., K _n . The output signals of the coefficient circuits 26 ₁ - 26 _n who selects the ge with the field frequency through the switch 28 and then fed to the adder 20 to add to the selected output signal of the switch 18 who the.

The signal applied to the input terminal 12 Stehbildvideosi gnal is further supplied via the A / D converter 14 a time clock generating circuit 30, the a Steuersi gnal for controlling the selecting operation of the switches 18 and 28 as well as various timing signals, such as an Si gnal for access to field memory 24 generated in synchronism with the still video signal. If, for example, a still image video signal of the ℓth partial image is supplied by or under the control of the timing generator 30 , the 18th coefficient circuit 16 _{1 is} selected (or controlled) by means of the switch 18 . Then an added output signal of the (ℓ-1) th field is read out of the field memory 24 and the ℓth coefficient circuit 26 _{1 is} selected.

On the other hand, the still video video signal output from the adder 20 , the noise or noise component of which has been reduced, is converted into an analog signal by the D / A converter 22 and then gelie via an output terminal 32 to the main part of a magnetic recording / reproducing apparatus, not shown finished.

Fig. 2 is a block diagram of an example of the timing generating circuit 30.

The still video video signal fed from the input terminal 12 via the A / D converter 14 is fed to the coefficients 16 ₁ - 16 _n and a vertical / horizontal synchronous separator circuit 34 is fed to the clock generation circuit 30 . As often as a vertical synchronizing signal and a horizontal synchronizing signal are supplied to a memory control circuit 36 , switching or switching selection signals for each field are fed to the switches 18 and 28 . This means that the switch positions of the switches 18 and 28 are changed sequentially with the field frequency, so that the output signals of the coefficient circles 16 ₁ - 16 _n and the coefficient circles 26 ₁ - 26 _{n can be} selected and sequentially fed to the adder 20 .

The horizontal synchronizing signal is fed to a phase locked loop 38 and locked by this phase locked ver, whereupon a clock signal, the phase of which is locked with the horizontal synchronizing signal, is supplied to the memory control circuit 36 .

The memory control circuit 36 controls the field memory 24 by supplying a memory read out signal and a memory write signal to the field memory 24 at a predetermined timing. The memory read signal is, for example, a chip select signal for selecting one of a plurality of memories, a read sample signal for controlling the data transfer from the memory cell array to the output register or a read address signal for designating the reception of a read address of the memory. The memory write-in signal is, for example, a chip select signal, a write-in strobe signal for controlling the data transfer from the input register to the write latch circuit, a write-in enable signal for controlling the writing of data from the write-in locking circuit into the memory cell array, or a write-in address signal for designating receipt of the write-in address of memory.

The following is the operation of the noise suppressor kungs circuit explained with the structure described.

First of all, it is assumed that coefficients K ₁ , K ₂ ..., and K _n for the coefficient circles 16 ₁ - 16 _n and 26 ₁ - 26 _n are set or specified as follows:

1- K ₁ = 1/2

1- K ₂ = 1/3

.

.

.

1- K _n = 1 / n

Accordingly, coefficients (1- K ₁ ), (1- K ₂ ), ..., (1- K _n ) of the coefficient circles 16 ₁ - 16 _{n are} each 1/2, 1/3, ..., or 1 / n set. Furthermore, coefficients K ₁ , K ₂ ..., K _{n of} the coefficient circles 26 ₁ - 26 _{n are} each set to 1/2, 2/3, ..., or (n -1) / n .

In this way, in this embodiment, the still video signal of the ℓth field is multiplied by 1 / ℓ, where ℓ is the order or number of reception of a field. The read output signal of the field memory 24 is multiplied with (ℓ-1) / ℓ. Consequently, let the the output terminal 32 supplied output still image signal SO and the output noise contained in the signal SO NO, he will be met if the operation of the recursive Addie proceedings of the input still image signal SI is completed by n fields, expressed as follows :

As can be seen from equation (10), the input image signal SI of each field is ultimately subjected to an addition with an addition coefficient of 1 / n . As a result, the level of the output image signal SO becomes equal to the level of the input image signal SI at the time of completing the recursive addition for n fields. The input image signal SI can thus be delivered without restriction from the D / A converter 22 to the output terminal 32 .

As can also be seen from equation (11), the input (image) interference signal NI of each field is ultimately subjected to an addition with the same addition coefficient. As a result, the output noise signal NO obtained by suppressing the input noise signal NI by 1 / √ can be fed to the output terminal 32 for n portions at the time of the completion of the recursive addition.

In the described embodiment, the addition coefficients of the (for the) input still image signal (s) and the (for the) read output signal (s) from the field memory 24 are therefore changed for each field as indicated. More specifically: an input still image signal of the ℓth field is multiplied by l / ℓ, while the read output signal from the field memory 24 is multiplied by (ℓ-1) / ℓ.

In the arrangement described, the same addition coefficient is set for the input noise NI of each field, and the input noise NI of each field can contribute to the noise reduction to the same extent in the last stage. As a result, a sufficiently large noise reduction effect can be obtained even when the number of addition fields (addition fields) is small.

In addition, the recursive circuit described uses only one field memory 24 , so that its size or dimensions can or can be kept small in comparison to a circuit with field memories for n addition fields.

Fig. 3 shows another embodiment of the invention, with respect to structure and operation of the parts of Fig. 1 corresponding parts with the same reference numerals as previously referred to and therefore are no longer explained individually.

According to Fig. 3 a signal fed from the input terminal 12 via the A / D converter 14 input Stehbildsi gnal adders 40 and 42 as well as the Zeittakterzeu supply circuit 30 is supplied. The output signal from the adder 40 is fed from the D / A converter 22 to the output terminal 32 and at the same time is written or read into the partial image memory 24 . The output signal from the field memory 24 is fed to the adder 42 , which in turn processes this output signal together with the input still image signal SI . This means that the adder 42 subtracts the read output signal or read output signal from the field memory 24 from the input still picture signal SI . The subtraction result is fed to a coefficient circuit 44 with a variable coefficient and multiplied by (ℓ-1) / ℓ. Furthermore, the output signal multiplied by the coefficient circuit 44 by (ℓ-1) / ℓ in the adder 40 is subtracted from the input still image signal. In this case, predetermined or preset control signals are supplied from the timing generating circuit 30 to the field memory 24 and the coefficient circuit 44 , the coefficient (ℓ-1) / ℓ of the latter being changed in accordance with the predetermined control signals.

As in the first described embodiment, in the second embodiment, an input still picture signal whose level is multiplied by 1 / ℓ and the read output signal which is read out from the field memory 24 and whose level is multiplied by (ℓ-1) / ℓ is won on the output side of the adder 40 ge. With the noise suppression circuit according to the second embodiment, the same effect as in the first embodiment is thus achieved.

In addition, since the coefficient circuit 44 with a variable coefficient (coefficient variable type) is provided in the second embodiment, the circuit dimensions can be reduced in comparison with the first embodiment, in which a plurality of coefficient circles with a fixed coefficient (coefficient fixed type) are provided .

The described embodiments relate to each a noise reduction circuit in which an on gangs freeze signal at a field frequency recur siv is added. However, the invention is not here limited to, but also apply to a circuit bar at which the input still image signal, for example is added recursively for each frame.

In the following, other embodiments of the inven tion are described with reference to FIGS . 4 and 5. The parts of the previously described embodiments are corresponding parts with the same reference numerals and are therefore not explained again in detail.

Fig. 4 shows the structure of a noise reduction circuit according to a third embodiment, which is similar to the embodiment of Fig. 1, except that the field memory is replaced by a frame memory. A still video signal is fed from the input terminal 12 via the A / D converter 14 to a number of n coefficient circuits 16 ₁ , 16 ₂ , ..., 16 _n and (by this) each with (1- K ₁ ), ( 1- K ₂ ), ..., or (1- K _n ) multiplied, and this signal is delivered to the timing generating circuit 30 at the same time. The output signals of the coefficient circuits 16 ₁ - 16 _n are selected as a function of control signals from the clock generation circuit 30 by the switch 18 and then fed to the adder 20 , the output signal of which is supplied via the D / A converter 22 to the output terminal 32 and simultaneously into one Frame memory 46 is written. The frame memory 46 is accessed depending on various timing signals provided by the timing generating circuit 30 , and the output signal of this memory becomes coefficient circles 26 ₁ , 26 ₂ , ..., 26 _{n of} an addition frame number (of addition frame number) (n) fed and multiplied by K ₁ , K ₂ , ..., or K _n . The outputs or output signals of the coefficient circuits 26 ₁ - 26 _n are selected by means of the switch 28 accordingly a predetermined control signal from the clock generation circuit 30 and then added by the adder 20 to the selected output signal of the switch IS . In this way, a still image signal with reduced noise or interference signal component is obtained from the adder 20 via the D / A converter 22 and the output terminal 32 .

As in the case of the first described embodiment, in the noise suppression circuit according to the third embodiment described above, the addition coefficients of the input still image signal and the readout output signal from the frame memory 46 are changed for each frame. This means that to implement the noise reduction, the input still image signal of the ℓth frame is multiplied by 1 / ℓ and the output signal from the frame memory 46 is multiplied by (ℓ-1) / ℓ.

Fig. 5 illustrates in a block diagram a fourth embodiment of the invention, which is similar to the embodiment of FIG. 3, only with the difference that the field memory is replaced by a frame memory. Accelerator as Fig. 5 is a signal supplied from the input terminal 12 via the A / D converter 14 input still image signal Ad decoding stages 40 and 42 and the timing generating TIC 30 fed. The output signal of the adder 40 is from the D / A converter 22 to output terminal 32 GELIE fert and simultaneously turned in the frame memory 46 written, the output signal provides ge to adder 42 and is processed by it together with the input still image signal SI; that is, the adder 42 subtracts the read or read output signal from the frame memory 46 from the input still picture signal SI . The subtraction result is fed to the coefficient variable circle 44 and multiplied by (ℓ-1) / ℓ. The output signal thus multiplied is subtracted from the input still image signal in the adder 40 . In this case, predetermined control signals are supplied from the timing generating circuit 30 to the frame memory 46 and the coefficient circuit 44 , and the coefficient (ℓ-1) / ℓ of the latter can be changed in accordance with the predetermined control signals.

As in the case of the embodiment according to FIG. 4, in the described embodiment according to FIG. 5 the input still image signal whose level is multiplied by 1 / ℓ and the output signal read out from the frame memory 46 , the level of which is (ℓ- 1) / ℓ is multiplied, on the output side of the adder 40, it is maintained or removed. With the described noise reduction circuit, the same effect is achieved as with the previously explained embodiments.

Since the embodiment of FIG. 5 are used to further koeffi zientenvariablen coefficient circuit 44, the circuit dimensions Kgs NEN compared to Anord voltage of FIG. 4, which uses a plurality of coefficient circuits with fixed coefficients can be decreased.

The invention is in no way based on the magneti mentioned cal recording / playback device limited, but e.g. also on a VTR or magnetic tape recording card mera applicable.

While a still picture signal is present at the input terminal 12 in the described embodiments, a dynamic picture signal can also be fed in in the manner described below.

When using the fixed coefficient circuits, as in the case of the first embodiment, the switches 18 and 28 , for example, are set to or into the predetermined switch positions by means of the clock generation circuit 30 . As a result, the same coefficient circles are always selected or controlled among the coefficient circles 16 ₁ - 16 _n and 26 ₁ - 26 _n . Even when a dynamic image signal is fed in via the input terminal 12 , a noise suppression effect can be achieved in this case, as in the case of a still image signal.

Claims (14)

1. Recursive noise suppression circuit for storing a still video signal from at least one field (field) and for recursively adding the same in order to reduce or suppress the noise component of the still video signal, comprising an A / D converter for converting the input still video signal into one Digital signal, an instantaneous coefficient unit for multiplying the digital signal converted by the A / D converter with a predetermined size, a recursive adding unit for sequentially and recursively adding a still image video signal of an immediately preceding field to the input or input still image video signal for the purpose of eliminating supply of the interference signal component contained therein from the digital signal multiplied by the instantaneous coefficient unit, a sub-image storage unit for storing the output signal of at least one sub-image (of) the recursive ad ding unit, a pre-or Before-coefficient unit for multiplying previous data of the still image video signal of the immediately preceding field, read from the field memory unit, with a predetermined size and for subsequently feeding the multiplication result to the recursive adding unit, a timing generator for accessing the field memory unit at a predetermined time or with a predetermined timing (at a preset timing) in synchronization with the still video signal and a D / A converter for converting the digital signal, the interference signal component of which has been eliminated and which is supplied by the recursive adding unit, into an analog signal, characterized in that that the instantaneous coefficient unit ( 16 ₁ , 16 ₂ , ..., 16 _n , 18 ) the converted by the A / D converter ( 14 ) converted digital signal with 1 / ℓ (with ℓ = receive order or order number of the still video gnals) multiplied and the multiplication energy b nis to the recursive adder unit ( 20 ), the before coefficient unit ( 26 ₁ 26 ₂ , ..., 26 _n 28 ) delivers the previous data of the still image video signal of the immediately preceding field, read from the field memory unit ( 24 ) with (ℓ -1) / ℓ multiplied and the multiplication result to the recursive adder unit ( 20 ) and the timing generation unit ( 30 ) provides access to the field storage unit ( 24 ) at the predetermined time or with the predetermined timing and a control signal for selecting the previous data the before coefficient unit ( 26 ₁ , 26 ₂ , ..., 26 _n , 28 ) to the before coefficient unit ( 26 ₁ , 26 ₂ , ..., 26 _n , 28 ). 2. Recursive noise suppression circuit for storing a still video signal from at least one field (field) and for recursively adding the same in order to reduce or suppress the noise or interference signal component of the still video signal, comprising an A / D converter for converting the input still video signal into one Digital signal, an instantaneous coefficient unit for multiplying the digital signal converted by the A / D converter with a predetermined size, a recursive adding unit for sequentially recursively adding a still video signal of an immediately preceding field to the input or input still video signal for the purpose of elimination of the interference signal component contained therein from the digital signal multiplied by the instantaneous coefficient unit, a sub-image storage unit for storing the output signal of at least one sub-image (from) the recursive ad ding unit, a pre- and pre- Coefficient unit for multiplying previous data of the still image video signal of the immediately preceding field, read out from the field memory unit, with a predetermined size and for subsequently feeding the multiplication result to the recursive adding unit, a timing generator unit for access to the field memory unit at a predetermined time or with a before a given timing (at a preset timing) in synchro nism with the still video signal and a D / A converter for converting the digital signal, the interference signal component has been eliminated and which is supplied by the recursive adder, into an analog signal, characterized in that the Instantaneous coefficient unit ( 16 ₁ , 16 ₂ , ..., 16 _n , 18 ) the current or available (current) data of the input still video video signal output by the A / D converter ( 14 ) with (1- K _ℓ ) (with ℓ = reception order or ordinal number of the Multiplied still video signal) and supplies the multiplication result to the recursive adding unit ( 20 ), the before coefficient unit ( 26 ₁ 26 ₂ , ..., 26 _n , 28 ) the previous data of the still video signal of the immediately preceding field, from the field storage unit ( 24 ) read out, multiplied by K _ℓ and the result of the multiplication to the recursive adding unit ( 20 ) delivers and the clock generation unit ( 30 ) accesses the field memory unit ( 24 ) at a predetermined point in time or with the predetermined clock rate and a control signal for selection the previous data of the before-coefficient unit (26 _1, 26 _2, ..., 26 _n, 28) for before-and-Koeffi zienteneinheit (26 _1, 26 _2, ..., 26 _n, 28) generates. 3. A circuit according to claim 2, characterized in that the instantaneous coefficient unit and the before coefficient unit each have at least two coefficient circuit units ( 16 ₁ , 16 ₂ , ..., 16 _n , 26 ₁ , 26 ₂ , ..., 26 _n ) comprise and the timing generation unit ( 30 ) a control signal for selecting the coefficient circuit unit ( 16 ₁ , 16 ₂ , ..., 16 _n ; 26 ₁ , 26 ₂ , ..., 26 _n ), which the previous data and the current Data in the before coefficient unit and the instant coefficient unit multiplied by a predetermined size, it produces. 4. A circuit according to claim 3, characterized in that the instantaneous coefficient unit and the before coefficient unit each have first and two te switching (er) units ( 18 , 28 ) for selecting a desired ge of the coefficients from or from the at least two Have coefficient circuit units ( 16 ₁ , 16 ₂ , ..., 16 _n ; 26 ₁ , 26 ₂ , ..., 26 _n ) in accordance with the control signal generated by the timing generator circuit ( 30 ). 5. A circuit according to claim 2, characterized in that (1- K _ℓ ) are 1 / ℓ and K _ℓ are (ℓ-1) / ℓ. 6. A circuit according to claim 1, characterized in that the before-coefficient unit and the eyes-coefficient unit include a data adding unit ( 42 ) for adding the input still video video signal output from the A / D converter ( 14 ) to the previous data of the still video signal in the immediately preceding field read out from the field memory ( 24 ) and (a) coefficient circuit unit (s) ( 44 ) for multiplying the output signal from the data adding unit ( 42 ) by (ℓ-1) / ℓ in accordance with the control signal from the Clock generation unit ( 30 ) and to deliver the multiplication result to the recursive adding unit ( 40 ). 7. A circuit according to claim 6, characterized in that the coefficient of the coefficient circuit unit ( 44 ) is selected in accordance with the control signal from the clock generation unit ( 30 ). 8. Recursive noise suppression circuit for storing a still video signal from at least one frame and for recursively adding the same to reduce or suppress the noise component of the still video signal, comprising an A / D converter for converting the input still video signal into one Digital signal, an instantaneous coefficient unit for multiplying the digital signal converted by the A / D converter with a predetermined size, a recursive adding unit for sequentially and recursively adding a still picture video signal of an immediately preceding frame to the input still picture video signal for the purpose of removing the into the sem contained interference signal component of the digital signal multiplied by the instantaneous coefficient unit, a frame memory unit for storing the output signal of at least one frame (from) the recursive adding unit, a before or before coefficient A unit for multiplying previous data of the still image video signal of the immediately preceding frame, read out from the frame memory unit, with a predetermined size and for subsequently feeding the multiplication result to the recursive ad unit, a timing generator for access to the frame memory unit at a predetermined time or with a predetermined time Timing (at a preset timing) in synchronism with the still video signal and a D / A converter for converting the digital signal, the noise signal component has been eliminated and which is supplied by the recursive adding unit, in an analog signal, characterized in that the Instantaneous coefficient unit ( 16 ₁ , 16 ₂ , ..., 16 _n , 18 ) the digital signal converted by the A / D converter ( 14 ) with l / ℓ (with ℓ = reception sequence or order number of the still image video signal) multiplied and the multiplication result to recursive n adding unit ( 20 ) provides, the before coefficient unit ( 26 ₁ , 26 ₂ , ..., 26 _n , 28 ) the previous data of the still video video signal of the immediately preceding frame, read from the frame memory ( 46 ), with K _ℓ multi and supplies the multiplication result to the recursive adder unit ( 20 ) and the clock generation unit ( 30 ) provides access to the full-frame memory unit ( 46 ) at the specified time or with the specified time and a control signal for selecting the previous data of the before-coefficient unit ( 26 ₁ , 26 ₂ , ..., 26 _n 28 ) to (for the) before coefficient unit ( 26 ₁ , 26 ₂ , ..., 26 _n , 28 ). 9. Recursive noise suppression circuit for storing a still video signal from at least one field (field) and for recursively adding the same in order to reduce or suppress the noise component of the still video signal, comprising an A / D converter for converting the input still video signal into one Digital signal, an instantaneous coefficient unit for multiplying the digital signal converted by the A / D converter with a predetermined size, a recursive adding unit for sequentially recursively adding a still video signal of an immediately preceding field to the input or input still video signal for the purpose of elimination the interfering signal component contained therein from the digital signal multiplied by the instantaneous coefficient unit, a sub-image storage unit for storing the output signal of at least one sub-image (of) the recursive ad ding unit, a pre-prev er coefficient unit for multiplying previous data of the still image video signal of the immediately preceding field, read out from the field memory unit, with a predetermined size and for subsequently feeding the multiplication result to the recursive adding unit, a timing generator unit for access to the field memory unit at a predetermined time or with a predetermined timing (at a preset timing) in synchronization with the still video signal and a D / A converter for converting the digital signal, the interference signal component of which has been eliminated and which is supplied by the recursive adding unit, into an analog signal, characterized in that that the instantaneous coefficient unit ( 16 ₁ , 16 ₂ , ..., 16 _n , 18 ) the current or present (current) data of the input still video video signal output by the A / D converter ( 14 ) with (1- K _ℓ ) (with ℓ = order or number of reception d it still video video signal) multiplied and supplies the multiplication result to the recursive adding unit ( 20 ), the before coefficient unit ( 26 ₁ , 26 ₂ , ..., 26 _n , 28 ) the previous data of the still video signal of the immediately preceding field, from the field storage unit ( 24 ) read out, multiplied by K _ℓ and the result of the multiplication is delivered to the recursive adding unit ( 20 ) and the clock generation unit ( 30 ) provides access to the partial image storage unit ( 24 ) at a predetermined time or with the predetermined timing and a control signal to select the previous data of the before-coefficient unit (26 _1, 26 _2, ..., 26 _n, 28) for before-and-Koeffi zienteneinheit (26 _1, 26 _2, ..., 26 _n, 28) generates. 10. A circuit according to claim 9, characterized in that the instantaneous coefficient unit and the before coefficient unit each have at least two coefficient circuit units ( 16 ₁ , 16 ₂ , ..., 16 _n ; 26 ₁ , 26 ₂ , ..., 26 _n ) comprise and the timing generation unit ( 30 ) a control signal for selecting the coefficient circuit unit ( 16 ₁ , 16 ₂ , ..., 16 _n ; 26 ₁ , 26 ₂ , ..., 26 _n ), which the previous data and the current Data in the before coefficient unit and the instant coefficient unit multiplied by a predetermined size, it produces. 11. The circuit according to claim 10, characterized in that the instantaneous coefficient unit and the before coefficient unit each have first and second te switching unit (s) ( 18 , 28 ) for selecting a desired one of the coefficients from or from the at least two Have coefficient circuit units ( 16 ₁ , 16 ₂ , ..., 16 _n ; 26 ₁ , 26 ₂ , ..., 26 _n ) in accordance with the control signal generated by the timing generator circuit ( 30 ). 12. Circuit according to claim 9, characterized in that (1-K _ℓ) equal to l /  andK _ℓ are equal to (ℓ-1) / ℓ. 13. The circuit according to claim 8, characterized in that the before-coefficient unit and the eyes-coefficient unit a data adding unit ( 42 ) for adding the A / D converter ( 14 ) outputted input still video signal to the previous data of the still video signal in the immediately preceding frame read out from the frame memory ( 24 ) and (a) coefficient circuit unit (s) for multiplying the output signal from the data adder unit ( 42 ) by (ℓ-1) / ℓ in accordance with the control signal from the clock generation unit ( 30 ) and for delivering the multiplication result to the recursive adding unit ( 40 ). 14. Circuit according to claim 13, characterized in that the coefficient of the coefficient circuit unit (s) ( 16 ₁ , 16 ₂ , ..., 16 _n ; 26 ₁ , 26 ₂ , ..., 26 _n ) according to the control signal from the timing generator ( 30 ) is selected.