FR2698752A1 - Magnification system for part of image contained in video signal - filters half-frames with vertical bandpass filter and horizontal high pass filter to enhance image - Google Patents

Abstract

The magnification is applied to a video signal delivered in an interlaced form by successive half-frames. The signal is initially applied to a preliminary filter that progressively combines the lines, then interpolates between them. A switching circuit selects odd and even half-frames. The half-frames are applied to a series filter having a bandpass characteristic in the horizontal plane and a high pass characteristic in the vertical plane. The central frequency of the bandpass filter corresponds to the desired image resolution. USE/ADVANTAGE - Partic. for contour correction. Image enhancement on video monitor e.g. for radiography.

Description

DEVICE FOR ENLARGING A PART OF A
IMAGE CONTENT IN A VIDEO SIGNAL.

 The present invention relates to a device for enlarging a portion of an image contained in a video signal. It can be used in particular for contour correction, or enlargements, of an image displayed on a monitor.

It finds its application particularly in the medical field where it is used to process digitized images from X-rays.

 When a body is examined, for example, that of a patient, X-ray, the X-rays that pass through this body are more or less absorbed by the cells of this body interposed in their path.

The intensity of X-radiation that leads downstream on a detector is indicative of the nature of these cells.

It is known to record the signal revealed by the detector in the form of a video signal, and to represent it on a monitor. In practice to perform signal processing on this signal it is preferred to switch from a detected analog video signal to a digital video signal with digital analog converters. For visualization, the digital video signal is converted back into an analog signal (with analog digital converters).

 One of the defects of X-ray images is that X-radiation, passing through the cells, sometimes gives rise to secondary emissions. These secondary emissions, also detected by the detector, are alterations of the image since they peddle in different points of the image artifacts that make this image blurred. Normally one can distinguish in a radiological image large structures, which correspond in practice to low spatial frequencies. On the other hand, small details, corresponding to high spatial frequencies, are then damped. In particular, the contours of the structures shown, corresponding to abrupt transitions of the image signal depending on whether one is projected in line with a mass or another different, are damped. Another effect decreases sharply. the contribution of the high spatial frequencies of the spectrum. It comes from the fact that an X photon received by the detector does not give a bright spot but a stain. Indeed, the incident X photon produces secondary X photons and electrons. The dispersion of these secondary photons and of these electrons in the scintillator material of the detector produces light photons distributed over a spot of considerable size. This light spot is the detected signal. Because of these phenomena, the radiological images all show a rapid decrease in the amplitudes of the spectral components, with the frequency.

 So we naturally seek to strengthen the contours: we try to increase the participation in the video signal of some spectral components located in the upper part of the spectrum. This reinforcement is obtained by filtering.

 To achieve this filtering, however, there is a particular difficulty with video images: normally the signal of these video images is presented with an interlacing of the lines so as to avoid annoying scintillation effect when viewing an image. We thus distinguish between half-odd and even-odd frames, which are displayed successively on the monitor, generally at a rate of fifty half frames per second, which gives a normalized rate of twenty-five frames per second for the total image. We will adopt here the concept of half-frame, commonly used, while the exact expression would be half-image. Normally to be filtered, the interlaced signal must be converted into a progressive signal.

 Indeed, the most convenient filters to use are the convolution filters. The principle of these filters is as follows. In a two-dimensional window of the image, a number of image elements, or pixels, contiguous are identified and the pixel in the center of the window is assigned a brightness that depends on the brightness of that point at center of the window as well as the luminosities of the points contiguous at this point in this window. This dependence is materialized by a set of coefficients: in practice the luminosity in the center is an accumulation of the luminosities of the contiguous points weighted by coefficients. The treatment therefore consists in theory of having the luminosities of the contiguous points and to make them support this algebraic combination. It is still necessary to have access to the contiguous points. It is for this reason that the signal must be progressive.

 A convolution is normally a combination in which all the pixels of an image contribute with adequate weighting to the filtered brightness of each of the pixels of the image. However, to limit the calculations, and therefore the processing time of computers that implement these combination algorithms, it is assumed that the convolution domain can be limited to a small number of contiguous points. Areas of nine points are thus known in which, in a matrix of three times three points, the brightness of the central point is a function of its eight neighbors. In the same way, domains of twenty five points are also known, corresponding to a window of five times five points. Preferably the matrices are of odd type because it will be easier to define a center of the window without having to shift the image. Nevertheless the invention could be applied to even matrices, four times four points for example.

 When the video signal of a half frame is delivered, there are of course only even lines or odd lines. Therefore, the neighborhood that is naturally obtained is an imperfect neighborhood. In particular because the most contiguous lines of the central line are not present. In practice, if one tries to filter this video signal with a convolution filter anyway, one obtains a different treatment of the contours according to whether they present a substantially vertical or horizontal trace in the image. For the horizontal plot, taking into account that the filter naturally uses the points directly contiguous to the central point of the window, we obtain a resolution double that which can be obtained on the vertical plane. Indeed, it acts in this case on points twice as tight.

 An attempt to avoid this kind of inconvenience has consisted in using windows of five times five theoretical points, with in practice five times three real points since two lines are absent, and to neutralize symmetrically by zero coefficients the luminosities. points in columns directly adjacent to the center of the window. Unfortunately, the experiment showed that the result obtained was not good. Indeed, the highest filtered spatial frequency can be in this case only half of that sought. In practice, we obtain convolutions of the same type as those taken on domains three times three points, but with additional constraints that lower the spatial resolution.

 Normally, the filter transfer function must be a bandpass function in order to be able to accentuate the central spatial frequencies corresponding to a given resolution. In high frequencies, the filter must be attenuator to eliminate the effects of electronic noise, and not seek to amplify too much a signal whose high frequency components have low amplitudes with respect to noise. This applies to the entire image.

 In the invention, by studying the spatial frequency spectra corresponding to each of the half images it was realized that one obtained a result quite acceptable if one simply submitted the video signal, delivered interlace in the form of half frame, to a filter having a high-pass transfer function on the vertical plane and a band-pass transfer function on the horizontal plane. In practice, the folding of the spectrum obtained with the filter gives a slightly worse result than with 5 x 5 filtering in progressive mode. This results in a slight calculated degradation of the signal-to-noise ratio of a few percent, and which is not visible nor measurable and therefore not troublesome. By performing a filtering on half frames, taking into account that the recomposition of the image on the screen by interlacing the half frames reverses one spectrum with respect to the other, we finally obtain for the vertical direction also a bandpass filter whose central frequency corresponds to the resolution to be obtained on the vertical plane, which preferably it is the same as the horizontal one.

 This same spectral study also led to an enlargement filtering to show an enlarged image of good quality. In fact, to enlarge an image, for example to double it, one uses a quarter of the initial image (a quarter of the half even field and a quarter of the half odd field), and one replaces four pixels of the image to show by one of the pixels of the starting image. Rather than taking image points as they are, one can choose to interpolate.

Normally the interpolation is not practiced in the old techniques because in all rigor in a duplicate line of a half frame we must interpolate the luminosities of the pixels of this duplicated line according to the pixels of the same line in the same half-frame and pixels of another line in another half-frame, of opposite parity, located above or below. In the invention with the same type of filter it is also possible to solve this problem.

 The subject of the invention is therefore a device for filtering a video signal, delivered in an interlaced form by half successive frames, characterized in that it comprises a filter having a high pass transfer function on the vertical plane in series in a circuit for transmitting this video signal, in order to obtain the equivalent of a band pass filter in progressive mode and thus perform an edge correction.

The invention also relates to a device for enlarging a part of an image contained in a video signal, delivered in an interlaced form by half successive frames, characterized in that it comprises
a circuit for progressively combining the lines of this video signal corresponding to a reduced height of the image to be represented enlarged,
an interpolation filter in series in a transmission circuit of this progressive signal, for interpolating the values of the lines of this signal
and a switching circuit for transmitting the progressive signal twice, once playing the role of a half even field and the other time playing the role of an odd half-field, and for modifying the filter coefficients of the filter at the same time. each change of half frame.

The invention will be better understood on reading the description which follows and on examining the figures which accompany it. These are given only as an indication and in no way limit the invention. The figures show
- Figure 1: a block diagram of filtering
according to the invention
FIGS. 2a, 2b and 3a, 3b: the shapes of the
spectra respectively of the image signal and the
video signal of half a frame, the filter according to
the invention acting on a half frame, and the
equivalent result of the filter of the invention
acting on the total image
- figure 4: the basic diagram of the filtering
magnification according to the invention
- Figure 5: a representation of the
combination of the lines of the half frames when
image enlargement.

Figure 1 shows the principle of the invention. A video signal 1 is in the form of two half frames respectively 2 and 3, odd and even. These two half frames are sent one after the other to a display monitor 4 where they are shown, interlaced with each other. In the invention, each half-frame is processed by a single filter placed in series in the transmission of this video signal. The filter 5 is, in the example described in this application, a convolution filter of the type
Cascading IMS sold by the INMOS Company, England. This filter is able in practice to store in digitized form the equivalent of a little more than two lines of the video signal, belonging to the same half frame. For example, it will be able to store the brightness values of the pixels of the lines L5, L7 and L9. As a new current point is added in the memory, concerning the line L9, a current point relative to the line L5 may be abandoned.

We can therefore consider that at any moment the circuit '5 has in memory the luminosities of the pixels situated between the one which has just been introduced and that which has just been ejected. Among these pixels it is possible to locate a window such as window 6, which in one example concerns the three lines, L5, L7 and
L9. The pixels are all adjacent to each other in these three lines.

 The current window 6 moves horizontally, from the beginning of a line to the end of a line, and vertically from a line each time an entire line has been completely read. It is known by switching and addressing circuits to have permanently available the brightness values of the pixels located in the window 6.

 The image point 7, located in the center of the window 6, receives as a brightness value to be displayed on the screen of the monitor 4 a brightness which is a function of its fifteen neighbors represented by small circles through the window 6. It will be noticed that its direct neighbors located in the even lines L6 and L8 are not taken into account (since in the end they will be introduced in the circuit 5 only when this one will treat the half frame 3), but that also the five points in each line L5, L7, L9 of the window are taken into account with non-zero coefficients.

 We will now explain the filtering functions. A low-pass filtering is intended to reduce the noise and rapid irregularities of the image, faster than the details that are sought to keep.

In practice, a compromise has to be made between noise improvement and the preservation of significant details. For example, in a window of three picture elements by three picture elements one can have a combination of type
121
1/16. 2 4 2
121
A smoothed image is then obtained. In order not to change the average level of the image, it is customary to normalize the matrix of the response by dividing it by the sum of the coefficients, hence the presence of the factor 1/16.

 The purpose of a high pass filter is to amplify the high spatial frequencies. It helps to enhance the contours. Such a result can be obtained by differentiating between the initial image and the smoothed image.

The two images possibly being weighted. In one example we take an initial image multiplied by twenty (each brightness value at points of the image is multiplied by twenty). This corresponds in practice to a convolution function of type 000
0 20 0 000
The high-pass filter result then has for combination coefficient the following results

<tb><SEP> 0 <SEP> 0 <SEP> 0 <SEP> 1 <SEP> 2 <SEP> 1 <SEP> -1 <SEP> -2 <SEP> -1
<tb><SEP> 0 <SEP> 20 <SEP> 0 <SEP> - <SEP><SEP> 2 <SEP> 4 <SEP> 2 <SEP> = <SEP> -2 <SEP> 16 <SEP> -2
<tb><SEP> 0 <SEP><.<SEP><SEP> 0 <SEP> 0 <SEP> 0 <SEP><SEP> 1 <SEP> 2 <SEP> 1 <SEP> r1 <SEP> - 2 <SEP> -l <SEP>
<Tb>
In practice; this last convolution is standardized by a factor of 1/4.

 With windows three times three, only low-pass filters or high-pass filters can be realized. The transfer function is monotonous. Windows five times five offer more flexibility than windows three times three to achieve a filter.

In particular, it is possible with them to obtain bandpass filters which are precisely those which are sought to obtain in the invention.

 The study of the invention which led to a band-pass filter on the horizontal plane and high-pass on the vertical plane is therefore compatible with this theory since on the vertical plane there are only three lines.

 In practice, to obtain an operator performing the same treatment on both dimensions of the image, it is sufficient in a preferred embodiment to calculate an operator having the effect of a high-pass filter in vertical corresponding to half of the bandpass filter in horizontal. One can thus determine a family of operators with a single parameter. This parameter is the boosting of the center frequencies of the bandpass filter. For this parameter, the one that gives the best result in contour reinforcement is chosen, the constraint of the half-frame processing is then no longer troublesome.

 In Figure 2a, there is shown the spectrum of the image signal. Naturally there are low frequencies in horizontal (U) and vertical (V) with significant amplitudes, and high frequencies on these two axes normally attenuated. FIG. 2b shows the spectrum of the video signal of each half field corresponding to the image signal of FIG. 2a. On the horizontal plane, nothing is changed.

 On the other hand, on the vertical plane, because of the half-sampling, the high frequencies of the basic signal (shown in draws) have folded positively, or negatively, in the half band of the spectrum. They have folded positively or negatively according to the parity of the frame. We then obtain one of the two spectral gaits shown in continuous lines for the Vertical space frequencies in Figure 2b.

 Figure 3a shows the spectrum diagram of the filter according to the invention. On the horizontal plane this filter has an overshoot corresponding to a spatial frequency f which itself corresponds to the resolution that we want to improve. The idea of the invention is to provide a high-pass filter for the vertical mode having the transfer function shown in Figure 3a. For low frequencies, the transfer function is 1, and for high frequencies, greater than or equal to the frequency f, it reaches the overshoot value C + 1.

 Figure 3b shows the actual result of the filter on the total image signal of Figure 2a. When we combine the two half frames together, this amounts to returning the vertical filter which, from high pass, becomes a bandpass.

The overshoot C, or contour enhancement coefficient, is compared to the basic amplitude of the signal. The ratio of central frequency enhancement is therefore C + 1. In practice C can vary from zero to a few units. The following table gives the coefficients of the filter according to the coefficient C:
-C-32 -C / 16 -C / 16 -C / 16 -C / 32
-3C / 16C / 8L + 5C / 8C / 8-3C / 16
-C / 32 -C / 16 -C / 16 -C / 16 -C / 32 where C represents the overshoot of the filter. These coefficients are to be applied as multiplicative weighting to the luminosities of the pixels of the window 6 which participate in the elaboration of the filtered brightness of the pixel 7. They parameterize the circuit mentioned above. The case of a treatment of three lines with five points per line has been studied.

With a circuit more powerful, more expensive, than that quoted one can treat five lines (even or odd) and nine points per line. Finally, we will treat n rows (n being preferably odd), and 2n-1 points per line. This is valid even if n is even.

 To obtain an enlargement of the image by a factor of 2, it is necessary to use the quarter of the initial image: it is necessary to reread a quarter of the memory corresponding to the useful part of the image. This is shown in FIG. 4 where the overall image is represented by the two half-frames 2 and 3 stored, and where quarter-frames 8 and 9 are respectively taken. To simplify the explanation, we took quarter half frames stalled at the top left of the image. But of course we can take these quarters of half frames at any place in the half frames 2 and 3, as long as they are taken at locations corresponding to one another.

 In a first process, the half lines of each of these quarter-frames are composed to form a quarter of an image in which the lines are presented in progressive mode. The quarter picture 10 can be stored in an intermediate memory and preferably it will be sent as such, in progressive mode, in the filter 5 of the invention.

 By taking again the elements of the figure 1 one can admit that the filter will thus receive the lines whose numbers follow each other, for example L1, L2, L3 and that there will always be constantly stored the equivalent of two lines (more five image points).

 To develop a first half (odd) frame 11 of the video signal to be shown on the monitor 4, the filter 5 will be weighted by a given set of coefficients. It will be shown later that in order to elaborate the lines of the other half-field (pair) 12, it will suffice to return the coefficients of the filter and to perform a reading in progressive mode of the quarter-image 10, or shifts 8 and 9 half odd fields 2 and 3 pairs if we do not want to use memory to store the intermediate image 10.

 This will be explained with reference to FIG.

On it we showed three half lines, the half lines corresponding to lines L1, L2 and L3 on the left side. Each of these half lines must be transformed into two whole lines including the number of points to show on the total width of the screen of the monitor 4. Roughly, the information content of the half line L1 must be carried in the line 1.1 and line 1.2, as well as line L2, line 2.1 and line 2.2.

We will then consider that lines 1.1, 2.1, 3.3, etc., are odd lines, marked by a small square, while lines 1.2, 2.2, and 3.2 are even lines, marked by a small circle.

 In the invention, the presence of the filter is used to perform further interpolation. One of the advantages of the invention is then to require only one circuit and to allow all the processing in real time. Nevertheless, we see that the interpolation differs according to the parity of the frame. For example, line L2 is shifted differently depending on whether line 2.1, very close to line L1 or line 2.2, is to be produced, very close to line L3. When it is necessary to elaborate the lines 1.1 or 2.1 or 3.1, etc ..., the interpolation filter will take into account the line of departure (L1) of lower rank to interpolate with this line (L2). By cons, to develop the lines (1.2) of the half frame of the other parity, we must take into account the row of higher rank (L3): simply the filter coefficients must be reversed.

When reading the half line L1, each image point must be split to fill an entire line (1.1 or 1.2) with only half of the original line. This can be done on the fly, either at the moment when the image is produced in progressive mode 10, or when the memory of the filter 5 is loaded. It suffices simply to write in this memory two once in succession each of the image points of the starting line L1. The convolution must produce the two half frames starting from this single (progressive) frame. We then change the coefficients of the convolution lteroperator between the production of the two half frames to obtain two half complementary frames. The circuit used, of the type mentioned above, therefore has two pages of coefficients that allow the change in progress. displaying an image. The functions of this circuit include:
a) the offset of the two half frames (offset
and interpolation in column) so the
duplication may not be brutal;
b) the interpolation of the image pixels in the
line;
(c) the contour correction, if any, if
wants to do it at the same time.

 This last contour correction retains symmetry. The offsets of the half frames being opposite; just calculate a coefficient table for a single offset direction. We then obtain the second by inverting the extreme lines of the table. In practice, we obtain a table of fifteen coefficients, as in the previous case, where to go from a half frame, 11, to the other, 12, it will read the table from bottom to top instead of reading from above below.

 Let L and L * be the operators corresponding to the two convolutions used for interpolation and contour correction. The global operator is calculated using translations Ju and Jv on each direction, respectively horizontal and vertical.

Let Jv and Jv * be the physical translation operators of +/- 1/4 of the pixel at the half-field offset, the two corresponding convolutions will be represented by two conjugated operators L and L *. The operator applied between the composed frame and the final image is JV.L + Jv * .L *
A real operator Z (without offset) is obtained between the original image and the enlarged image which is to perform the interpolation plus the contour correction.

Let Z = (JU + JU *) (LJv + L * Jv *) where Ju and Ju * represent the effect of splitting the pixels in each line. This defines a combined filter such as
Z corresponds to the conditions imposed above. The physical translation of these conditions concerning the operator Z is a bandpass filter whose transmission factor is 1 at low frequencies, C at an intermediate frequency and 0, with a horizontal tangent, for the maximum frequency of Nyquist.

In the phase J space is written:
J (v) = ej7Tv / 2
The development on the u, v mark leads to a form:
2 2
Z (u, v) = C z cos cos (ff (2p + 1) u / 2). Cos (ff (2q + 1) v / 2)
p = 0 q = 0
The table Cpq includes 9 terms related to the coefficients aij of the operation by simple linear relations i = 0 if q = 0
Cpq = aip + ai (p + 1) with
i = (-l) q If qp 0
The study of the operator is more easily done on the table Cpq to which the conditions are imposed:
1. Normalization z C pq = 1
2. Interpolation which gives 6 relations of the
form 5p (-1) P (2p + 1) Cpq = 0 of which 5 are independent. These relations allow the calculation of 6 coefficients according to the 3 others.

 In addition, it is preferable to impose additional constraints, maximum value given in all directions of the plane u, v, and existence of a single maximum. A least squares optimization program was performed on the additional conditions. Its operation is as follows: we give a table aij giving an approximate solution of the coefficients and the program searches by successive approximations which is the best solution answering the imposed conditions. The search is made following the line of greatest slope towards the minimum of the squares of the gaps, in the space of the independent parameters.

The general solution found for the operator L is then a linear form as a function of a single parameter: a + CB, where:
-15/512 5/128 35/256 5/128 -15/512 a = -15/256 15/64 75/128 15/64 -15/256
-3/512 -3/128 -9/256 -3/128 -3/512 and
-5/64 -1/16 1/32 -1/16 -5/64 ss = -5/32 1/8 9/16 1/8 -5/32
-1/64 -1/16 -3/32 -1/16 -1/64 and where C is the contour enhancement parameter.

In the useful domain C varies between 0 and some units. When C is 0, only the interpolation is performed without contour enhancement. When C is 1, an edge enhancement of the order of 1.55 is obtained. Preferably, C is between 0 and 1.

 For a half frame 11 the table is the one above, for the other half frame 12 the table is the same but with lines of extreme coefficients inverted.

Claims (7)

 1 - Device for enlarging a part of an image contained in a video signal, delivered in an interlaced form by half successive frames, characterized in that it comprises  a circuit for progressively combining the lines of this video signal corresponding to a reduced height of the image to be represented enlarged,  an interpolation filter in series in a transmission circuit of this progressive signal, for interpolating the values of the lines of this signal  and a switching circuit for transmitting the progressive signal twice, once playing the role of a half even field and the other time playing the role of an odd half-field, and for inverting lines of filter coefficients of the filter every half frame change.  2 - Device according to claim 1, characterized in that it comprises  a combined filter so that the total filtering obtained on the image is a bandpass filter with interpolation.  3 - Device according to claim 1 or claim 2, characterized in that the video signals are digitized and in that the filters are digital convolution filters whose convolution domain is a restricted domain to three lines, all pairs or odd according to the type of the half frame being filtered, and at five points per line, in which preferably the coefficients are of the type a + C, where:  -15/512 5/128 35/256 5/128 -15/512 a = -15/256 15/64 75/128 15/64 -15/256  -3/512 -3/128 -9/256 -3/128 -3/512 where:  -5/64 -1/16 1/32 -1/16 -5/64 B = -5/32 1/8 9/16 1/8 -5/32  -1/64 -1/16 -3/32 -1/16 -1/64 and where C, which represents the overshoot of the center frequencies of the band pass filter, is worth a value between zero, when we do not want to contour correction and one when this correction is applied.  4 - Device according to any one of claims 1 to 3 for filtering a video signal, delivered in an interlaced form by half successive frames, characterized in that it comprises a filter having a high transfer function on the plane serial vertical in a transmission circuit of this video signal, to obtain the equivalent of a bandpass filter in progressive mode and thus achieve contour correction.  5 - Device according to claim 4, characterized in that the filter is a digital convolution filter for filtering a digitized video signal on 2 n-1 points of a line in n lines, n being preferably odd.  6 - Device according to claim 5, characterized in that the convolution domain of this filter is a restricted domain to three lines, all pairs or odd according to the type of the half frame being filtered, and five points per line.  7 - Device according to claim 6, characterized in that the coefficients of this filter are of the type:  -C-32 -C / 16 -C / 16 -C / 16 -C / 32  -3C / 16C / 8L + 5C / 8C / 8-3C / 16  -C / 32 -C / 16 -C / 16 -C / 16 -C / 32 where C represents the overshoot of a resulting bandpass filter in the image.