FR2722938A1 - Parameter adjustment for X-ray apparatus esp. for medical imaging radiology - Google Patents

Abstract

The parameter adjustment involves two parameters (P1,P2) which allow adjustment of the radiological unit. The first parameter is voltage, the second exposure time. Each parameter has a desirable range of adjustment (inf,sup) and an acceptable range of adjustment (min,max). A set of range zones can be defined where the parameter (P1) is in the desired range, but not P2 (A,B), and a set where the parameter P2 is in the desired range but not P1(C,D). A central zone (G) represents the region where both parameters are optimal. When a body absorption factor is called by the practitioner, the voltage is adjusted first to within its desirable range, working on the exposure time parameter to keep this within the desirable range. If parameters cannot be adjusted in the desirable ranges, the acceptable range is chosen for one of the parameters.

Description

OPERATING PARAMETER (S) ADJUSTMENT METHOD
OF A CORRESPONDING RADIOLOGICAL APPARATUS AND GENERATOR
Technical area
The subject of the present invention is a method for adjusting the operating parameter (s) of a raciological examination apparatus and a corresponding generator.

State of the art
An apparatus for radiology and, in particular, a medical radiolosle, very schematically comprises an X-ray source, a generator, for example of high voltage, supplying this source, and an image receiver constituted by a film or an intensifier. of radiological image (IIR) possibly associated with digital image acquisition means The patient is placed between the X-ray source and the image receiver.

 The generator supplying the X-ray source delivers an electrical voltage of the junk of a few tens of kilovolts, under a certain current intensity, of the order of a few milliamperes up to a few amperes, for a certain period, called the time of pose, which is usually counted in illiseconds. The dose of X-rays received by the patient depends, among other things, on the product of intensity by the exposure time. The image receptor receives only part of this dose, depending on the absorption of the patient.

 The electrical parameters of a radiological examination (voltage, current, time) are adjusted according to the desired image quality and according to the type of examination undertaken. For example, the contrast will be as much better as the tension will be lower and the quality of the image will be all the greater as the effect of camera shake will be reduced, i.e. the exposure time will be low. With regard to the type of examination carried out, there is, for example, a radiography of the bones where the immobility of the areas observed allows a long exposure time and where the focus is on adjusting the tension to obtain the best possible contrast , and an examination of the nitrogen car region where the proper movement of the organs requires a short installation time, but leaves a more free choice for tension.

 In the state of the prior art, these parameter settings are performed either manually or automatically, in which case the practitioner is not called upon and can then concentrate on the image.

 Methods are known for calibrating a radiological system and for measuring the equivalent thickness of an object. The equivalent thickness of an object is defined in relation to a reference material, such as Plexiglas for example. Under precise radiological conditions, that is to say with a fixed configuration and setting parameters, the equivalent thickness of a patient is represented by the thickness of the reference material providing the same energy to the detector.

 Document --A-A-2 648 229 describes such a process.

 In what follows, “regulated X-ray emission” will denote both an X-ray controlled by an automatic exposure device and a radioscopy at constant dose rate at the entrance to the IIR.

 The equivalent radiological thickness of the patient is calculated from a calibration of the generator and a regulated emission of X-rays beforehand.

 This same calibration makes it possible to calculate the product of the intensity by the necessary exposure time associated with a tension-thickness pair, this product making it possible to carry out an exposure under conditions equivalent to those of a regulated emission this X-rays.

This process works for any image acquisition method (f-lm, digital acquisition,
In known devices, the extreme limits of the parameters (minimum technological value, maximum technological value) depend on the technical characteristics of the generator and the radiological system.

 If this method is interesting in certain respects, it nevertheless has a drawback which is its lack of flexibility. The practitioner cannot express his preferences or exercise a prior choice with regard to the various operating parameters, depending on the desired contrast or fineness, depending on the circumstances, etc.

 The object of the present invention is precisely to remedy this drawback.

Statement of the invention
To this end, the present invention provides a method for adjusting the parameters of an X-ray device taking into account the preferences of the user.

For this, the invention provides that one defines, within the interval limited by the minimum technological and maximum technological values of any given operating parameter of the radiological device, a second interval defined by a value radiological minimum and a maximum radiological value, hereinafter referred to as minimum and maximum values. This second interval will be designated by "accepted interval" to show that the values falling therein are, if not ideal, at least acceptable. I is also defined, within the accepted interval, a third interval defined by a lower value and a higher value. This third interval will be designated by "desired interval" because it is within this privileged interval that the user wishes to operate. provision is therefore made for the operating parameter considered to be able to be positioned automatically within its associated desired interval, if necessary by modifying the value of one or more other operating parameters of the radiological device. If this is not possible, this automation attempts, by the same means, to position the parameter of
Operation considered within its associated accepted interval.

 Several operating parameters of the radiological device can be affected by this process. In this case, a priority is defined between parameters, each attempt to position a given parameter acting only on parameters of lower priority. A parameter for which no interval would be entered is considered here as having the lowest priority.

Specifically, the present invention relates to a method for adjusting at least one operating parameter of a radiological examination device, characterized in that it comprises the following operations
a) choose beforehand an accepted range of values for this parameter, this range being defined by a minimum value and a maximum value,
b) choose beforehand a desired range of values for this parameter, this range being included in the accepted range and being defined by a lower value and by a higher value,
c) automatically determining a first value of the parameter to be adjusted taking into account the type of examination to be performed and the patient to be examined,
d) examine If this first value falls within the desired range and,
dl) if so, consider that the
adjustment is complete,
d2) if this is not the case, modify at
minus another parameter of
functioning to seek to bring the
value of the parameter to be set in
the desired interval and,
d21) if possible, consider
that the setting is complete,
d22) if this is not possible,
modify this or these others
parameter (s) to bring the value of the
parameter to be set in the meantime
accepted.

 If the last adjustment is not possible, a warning signal can be sent.

 The invention is not limited to the adjustment of a single parameter, but extends to any number of parameters. In this case, a hierarchy is defined in these parameters, that is to say an order of priority. A parameter having a certain priority is then adjusted by modifying the value of one or more lower priority parameter (s), the adjustment starting with the parameter having the highest priority and ending with the parameter having the lowest priority.

 Any parameter can be the subject of the method of the invention: the voltage, the exposure time, the intensity of the current, the dose received by the patient or by the image receptor, etc.

 According to a preferred, but not exclusive, mode of implementation, the voltage and the exposure time are thus received by prioritizing the voltage over time or vice versa.

 The invention also relates to a generator implementing the method which has just been defined.

Brief description of the drawings
- Figure i is a diagram of an X-ray machine
- Figure 2 is a diagram showing the different possible operating ranges in the case of two parameters
- Figure 3 shows a flowchart illustrating the different operations implemented in the method of the invention.

Detailed description of an embodiment
Figure 1 shows the general structure of a radiology device. We see there a source 10 of X-rays, a patent 12 placed opposite this source, a device 14 able to capture the X-rays transmitted by the patient and to receive an image, a high voltage generator 16 connected to the source 10 by a high-voltage cable 17 and connected to the device 14 by a connection 15 capable of carrying information on the transmitted X-ray, and finally auxiliary means 18 capable of fulfilling various functions specific to the radiological system.

 In the description which follows, we will focus more particularly on the case where two operating parameters are set, namely the voltage and the exposure time. But this case is not limiting.

 We will denote by Pi the first parameter, namely the voltage, and by 2 the second, namely the exposure time. It is also assumed that P1 (the voltage) has priority over P2 (the exposure time).

 We define con a "desired" interval and an "accepted" interval for Pi and for P2.

 The value of P1 is then determined by automatic means compressing, inter alia, the measurement of the equivalent absorption of the patient. If P1 is not in its desired interval, one acts on P2 while maintaining P2 in its accepted interval to enter P1 in its desired interval. If this is not possible, we are content to maintain P1 in its accepted interval while still dedicating to P2, but by maintaining P2 in its own accepted interval.

 FIG. 2 shows the different possible cases for the pair of parameters P1, P2. The values of the PI parameter are plotted on the x-axis and those of the P2 on the y-axis.

For each parameter, there are four values setting limits: minimum ("min"), lower ("inf"), upper ("sup") and maximum ("max");'interval [Terminal "min"; Terminal "max"] is the "accepted" interval. The interval [Terminal "inf";
Terminal "sup"] is the "desired" interval.

Zones A and 3 correspond to the case where P1 is in the desired interval, but not P2. Areas
C and D correspond, conversely, to the case where P2 is in its desired interval, but not P1. The central zone G is the optimal zone where the two parameters are in their desired interval. The zones E and F correspond to the cases where Pl and P2 are both within their accepted intervals.

 The diagram in FIG. 2 is valid whatever the nature of the parameters P1 and P2.

By way of explanation, it can be indicated that they are the ranges generally used for radiology devices.
- for the voltage, it is generally between 20 and 15C kV,
- for the exposure time, these are durations ranging from 1 to 6400 ms,
- for the intensity, it varies between 10 and 1250 mA.

 The intensity and the tension, by their product, define the thermal load of the X-ray tube. This product is generally limited superiorly, according to the type of tube used.

FIG. 3 shows a flowchart illustrating the method of the invention in the case of a single parameter, in this case the voltage. The different blocks have the following meaning
20: regulated X emission (fluoroscopy or spelling),
22: measurement of the equivalent radiological thickness,
24: epalssor-.ension correspondence,
26: internal calibration,
28: calculation of the product of intensity over time
installation required for a tension-thickness pair,
and calculation of the exposure time according to the thickness, the
voltage, thermal state of X-ray tube, etc.

30: is the voltage in its interval
wish ? 32: end of the process If the answer to the question
previous is affirmative, 34: can we modify one or more parameter (s) (in
preserving conditions equivalent to those
of a regulated X emission) in order to position the
tension in its desired range? 36: end of the process if the answer to the question
previous is affirmative, 38: can we modify one or more parameter (s) (in
preserving conditions equivalent to those
of a regulated X emission) in order to position the
tension in its accepted interval? 40: end of the process if the answer to the question
previous is affirmative, 42: if the answer to question 38 is negative a
warning can be produced to prevent
failure to implement the process.

Claims (2)

RESELL I CAT IONS Method for adjusting at least one operating parameter of an X-ray examination apparatus, characterized in that it comprises the following operations a) choose beforehand an accepted interval of values for this parameter, this interval being defined by a minimum value and a maximum value, b) beforehand choosing a desired interval of values for this parameter, this interval being included in the accepted interval and being defined by a lower value and by a higher value,  c) automatically determining a first value of the parameter to be adjusted taking into account the type of examination to be performed and the patient to be examined,  d) examine whether this first value falls within the desired range and,  dl) if so, consider that the  adjustment is complete,  d2) if this is not the case, modify at  minus another parameter of  functioning to seek to bring the  value of the parameter to be set in  the desired intervention and,  d21) if possible, consider  that the setting is complete,  d22) it's not possible,  modify this other  parameter (s) to bring the value of the  parameter to be set in the meantime  accepted.  2. Method according to claim 1, characterized by the ait zue, if the last adjustment is not possible, a warning signal is emitted.  3. Method according to claim 1, characterized in that several parameters, each defined by an accepted interval and by a  n desired interval, are set, a priority order being defined between the different parameters, a parameter having a certain priority being adjusted by modifying the value of a parameter or several parameters of lower priority, the adjustment starting with the parameter having the most high priority and ending with the parameter with the lowest priority.  4. Method according to any one of claims 1 to 3, characterized in that one of the parameters set is voltage.  Method according to any one of Claims 1 to 3, characterized in that one of the parameters set is an exposure time.  6. Method according to any one of claims 1 to 3, characterized in that one of the parameters set is a current intensity.  7. Method according to any one of claims 1 to 3, characterized in that one of the parameters set is a dose of radiation.  8. Method according to claim 3, characterized by the fact that a first parameter (P1) is set which is a voltage and a second parameter (? 2) is set which is an exposure time, the voltage having priority over time, the voltage being adjusted by action on time and time being adjusted by action on one or other parameters without priority.  9. Method according to claim 3, characterized in that a first parameter (P1) is set, which is an exposure time and a second parameter (P2) is set, that is a voltage, the exposure time having priority over the voltage, the exposure time being adjusted by action on the voltage and the voltage being adjusted by action on one or other parameters without priority.  10. Method according to any one of claims 1 to 9, characterized in that an operating parameter for which desired and accepted intervals are not defined is considered to have the lowest priority.  Generator for radiological examination apparatus, this generator implementing the method of revenàicatiz 1 and comprising  a) first means capable of delivering an electrical voltage at a certain intensity for a certain time, these voltage, intensity, time constituting as many operating parameters of the radiology device,  b) second means capable of automatically determining a first value of the parameter to be adjusted taking into account the type of examination to be performed and the patient to be examined, this generator being characterized in that it comprises  c) third means able to define an accepted range of values for at least one parameter, this accepted range being defined by a minimum value and a maximum value and to define a desired range of values for the parameter, this desired range being included in the interval accepted and being defined by a lower value and by a higher value,  d) fourth means capable of examining If the first value determined by the second means falls within the desired range of the parameter to be adjusted and  dl) if so, able to do  deliver by the generator the parameter  in question at its first value,  d2) if not, suitable for  modify at least one other parameter of  operation to bring the value of  parameter to be set in the meantime  desired and  d21) if possible, able to do  deliver by the generator the  parameter in question at value  obtained,  d22) s; it is not possible, apt  to modify this other or these others  parameter (s) to seek to bring  the value of the parameter to be set in  the interval accepted.  12. Generator according to claim 11, characterized in that it comprises means for delivering a warning signal when the last adjustment is not possible.  13. Generator according to claim 11, characterized in that it further comprises means for choosing a priority order between several parameters to be adjusted, said fourth means then being able to adjust a parameter having a certain priority by modifying the value one or more lower priority parameter (s), the setting starting with the parameter having the highest priority and ending with the parameter having the lowest priority.  14. Generator according to claim 13, characterized in that the fourth means regulate in first priority the voltage and in second priority the exposure time.  15. Generator according to claim 13, characterized in that the fourth means regulate in first priority the exposure time and in second priority the voltage.  16. Generator according to any one of claims 11 to 15, characterized in that an operating parameter for which desired and accepted intervals are not defined is considered to have the lowest priority.