DE102012201452A1 - Method for operating x-ray system, particularly radiography system, involves exchanging time-uncritical user data with main unit by x-ray detector through synchronous radio path, where dose measuring device generates time-critical signal - Google Patents

Abstract

The method involves exchanging the time-uncritical user data (10) with a main unit (4) by an x-ray detector (8) through a synchronous radio path (12), where a dose measuring device (20) generates a time-critical signal (S), which correlates with an incident x-ray dose (D), in the x-ray detector. The x-ray detector transmits the signal in the form of a transmission signal to the main unit over an asynchronous radio path (22). The x-ray system (2) is operated depending on the signal. The x-ray detector generates a series of dosing quantities of counting pulses assigned to the x-ray dose.

Description

The invention relates to a method for operating an X-ray system that includes a wireless X-ray detector.

In X-ray systems, in particular in radiography equipment, increasingly wireless, portable X-ray detectors, in particular in the form of flat detectors are used. Such an X-ray system has, in addition to the detector, a basic unit which contains an X-ray source. It is known that the X-ray detector exchanges user data with the base unit via a radio link. For example, these are image data or status data of the detector generated in the detector. The radio link is the use of a W-LAN according to IEEE standard 802.11an known. W-LAN provides a so-called synchronous radio link, which can be called clock-based, packet-based or digital.

It is known to use the X-ray detector for the production of X-ray images in an X-ray table or a raster wall device. There, a fixed automatic dose control system (present, for example, the voltage in kV Automatic Exposure Control) or its dose measuring device is then present next to the detector. In the case of the AEC, a limit dose delivered by the source or to be received by the X-ray detector or the dose measuring device is preset and the X-ray source is automatically switched off when this dose is reached. The dose is specified. If there is no AEC, e.g. the voltage in kV and the current-time product in mAs given, what one calls two-point technique. The AEC works between the dose control system and the basic unit. For example, in the dose measuring device, a semiconductor measuring chamber counts events generated by X-ray radiation. Optionally, a summation of the accumulated from a certain start time dose. However, if the X-ray detector is used independently of such a fixed dose control system, that is, a free recording takes place, a corresponding AEC is not possible.

It is known to integrate a dose measuring device in the mobile X-ray detector. These are additional elements for dose determination, usually below the photodiodes. This can e.g. Semiconductor measuring chambers be. The dose information collected here is usually in the form of a counter, that is, depending on the impact of a dose in the measuring chamber, a higher count is achieved. The signal carrying the dose information of the integrated dose measuring device is usually digitized prior to transmission. The transmission of the dose information then takes place via the o.g. synchronous radio link from the X-ray detector to the base unit or to the X-ray source. However, the synchronous radio link operates clock-based, with the clock cycle prescribed for an AEC having too long clock cycles. The shutdown information generated in the X-ray detector can not be forwarded quickly enough to the X-ray source so that it remains in operation for too long and an unacceptably high X-ray dose arrives in the detector. In other words, the synchronous radio link is not real-time capable in this respect.

In the known X-ray detector, therefore, a trial recording is first made with estimated X-ray dose, i. without AEC. The actual dose determined during the recording is then transmitted to the base unit only after its end, that is to say at a later time, and processed there. If necessary, a new recording is made with a correspondingly adjusted preset dose. So you may need multiple shots. An accurate dose setting or AEC is not possible.

The object of the present invention is to provide an improved method for operating an X-ray system with a portable wireless X-ray detector.

The object is achieved by a method according to claim 1 for operating an X-ray system with a base unit with X-ray source and a portable wireless X-ray detector. The X-ray detector exchanges non-time-critical payload data with the basic unit via a synchronous radio link. A dose measuring device in the X-ray detector generates a time-critical signal correlated with an incident X-ray dose. The X-ray dose is detected by the dose measuring device on the detector. The X-ray detector transmits the signal in the form of a transmission signal via an asynchronous radio link to the basic device. The dose control of the X-ray system is operated on the basis of the signal.

The X-ray dose is the one that is incident, for example, in a measuring chamber of the dose measuring device. It represents a measure of the incident in the entire detector or emitted by the X-ray source X-ray dose. The quantitative measurement of the X-ray dose usually takes place only during operation of the X-ray source, so from their activation or activation, for example, for the generation of a single X-ray image. The correlation occurs, for example, in that the dose incident on a small area of a measuring chamber is extrapolated to the detector area or to the dose radiated by the X-ray source. The transmission signal is received in the basic unit and then also throughout X-ray system further processed and used so as to operate the X-ray system accordingly. This also means the utilization of the information of the signal via the X-ray dose measured at the dose measuring device. For example, the transmission signal can be evaluated in particular by the X-ray source as shutdown information.

The asynchronous radio link can also be referred to as a real-time or analog radio link. The respective information transmission takes place in contrast to the synchronous radio link not only in pitches, but always immediately. The transmission signal is usually digitized after reception in the basic unit in order, for example, to to be processed by the software of the X-ray source.

The invention is based on the recognition that a real-time transmission of the dose information from the X-ray detector to the rest of the X-ray system is necessary in order to obtain e.g. to realize an AEC also in conjunction with a mobile X-ray detector, that is to be able to switch off the radiation of the X-ray source in response to a dose measurement at the detector without delay. The invention is based on the idea of dividing the total data in the X-ray detector into non-time-critical payload data and time-critical signals. The non-time-critical payload data here are, for example, X-ray image and status data, in each case no dose information necessary for the AEC. Only the latter are time critical for the AEC. Furthermore, the knowledge is used that an asynchronous radio link works without delay and serves for a real-time radio transmission, since a signal transmission can take place immediately. Time-critical means in the context of the invention that the corresponding signal must be treated more timely and faster than the non-time-critical payload. In other words, the processing and transmission of the time-critical signal or transmission signal in the entire X-ray system is always instantaneous, that is to say on such a fast signal path which, depending on the application, e.g. for an AEC, is still acceptable.

In other words, the invention consists in generating a signal which, during operation of the X-ray source, is correlated with the X-ray dose currently emitted or arriving at the detector; to transmit this signal via asynchronous radio link, in real time from the X-ray detector to the rest of the X-ray system or to the X-ray generator; and operate the X-ray system virtually delay-free depending on the signal. The advantage here is that the time-critical dose information is transmitted asynchronously or analogously by radio in real time, while the image information continues to be known synchronously or digitally and slightly delayed transmitted via WLAN.

In a preferred embodiment of the invention, the X-ray detector generates a sequence of counting pulses as a transmission signal. Each count pulse is associated with a respective incident dose amount of the X-ray dose. In this case, the dose quantity is, for example, a dose that is minimally detectable in the dose measuring device, in a particular embodiment, for example, a single X-ray quantum.

The asynchronous or analog radio link can in this case, for example, transmit each counting pulse as a defined rectangular signal of a specific amplitude. If a desired target dose determined from the transmission signal is then determined to have been reached in the basic unit, a generator switches off a high voltage at the x-ray source and thus the x-ray radiation. For example, PMR 446 (from 446.0 to 446.1 MHz with a maximum transmission power of 500 mW) can be used as the frequency range for an asynchronous radio link. This frequency range can be freely used in most countries. But it is also conceivable every other shared frequency range.

In an alternative embodiment, the dose amount corresponds to a value that is correlated with a predeterminable total dose. In other words, for example, counting pulses generated by a measuring chamber are first pre-processed into a sum value in the X-ray detector. This then represents the value to be transmitted for the transmission signal and is transmitted. Correlated means here: The value can either be the o.g. Total dose, or even parts of the total dose, for example, the halves, thirds, quarters, 10% increments, etc. of the total dose.

In a preferred embodiment, the X-ray detector continuously forms a sum value of the X-ray dose measured in the dose measuring device as the transmission signal. The transmission signal is then transmitted continuously. The basic device is thus always up to date on the accumulated in the detector sum value.

In a further preferred embodiment, the X-ray system is operated on the basis of the transmission signal such that the base unit from the transmission signal o.g. or alternative sum value of the X-ray dose is determined and the X-ray source then turns off when the sum value reaches a limit. The sum value is formed here, for example, from the start of an X-ray image recording.

The above-described characteristics, features, and advantages of this invention, as well as the manner in which they are achieved, become clearer and more clearly understandable with the following description of the embodiments, which are explained in more detail in connection with the drawings.

For a further description of the invention reference is made to the embodiments of the drawings. They show, in each case in a schematic outline sketch:

1 an x-ray system operated by means of the method according to the invention,

2 a signal and transmission signal,

3 an alternative transmission signal,

4 another alternative transmission signal.

1 shows an x-ray system 2 with a basic device 4 with an X-ray source 6 and with a portable wireless x-ray detector 8th , The basic device 4 also includes an image system 14 and a W-LAN access point 16 , This is via a wired connection 18 with the picture system 14 connected. During its operation, the X-ray detector generates 8th non-time-critical user data 10 in the example X-ray image information and status data of the X-ray detector 8th , The X-ray system 2 has a synchronous radio link 12 on, over which the X-ray detector 8th the user data 10 with the basic device 4 exchanges. In the example, the synchronous radio link 12 a W-LAN connection from the X-ray detector 8th to the W-LAN access point 16 ,

In the X-ray detector 8th is a dose measuring device 20 integrated. This generates a signal S, which with a in the Dosismesseinrichtung 20 incident X-dose D is correlated. In the X-ray system 2 should an AEC be realized. Since the signal S carries dose information, it is time-critical with respect to the AEC, that is must as fast as possible in the basic unit 4 be further processed. The synchronous radio link 12 is not suitable for this, since their signal transmission operates clock-oriented. In the intervals between the clocks no information transmission is therefore possible. The X-ray system 2 therefore additionally has an asynchronous radio link 22 between x-ray detector 8th and basic device 4 on. The asynchronous radio link 22 is an analog radio connection in the example. The x-ray detector 8th transmits over this the signal S in the form of a transmission signal T to the basic unit 4 , The basic device 4 evaluates the transmission signal T with respect to the signal S and uses the dose information contained therein to the entire X-ray system 2 to operate in dependence of this signal S.

2 plotted against the time T, the course of the signal S from 1 if at time t ₀ the X-ray source 6 is switched to an X-ray image in the form of the payload 10 in the X-ray system 2 to create. At respective times t _z , a respective dose quantity M is new in the dose measuring device 20 collapsed, whereupon this one counting pulse 24 outputs. The dose amount is an X-ray quantum or other dose amount. The transmission signal T therefore represents a rectangular signal which is then emitted by the X-ray detector 8th over the radio link 22 is transmitted.

3 shows an alternative signal S over time t, again starting at time t ₀ an X-ray. Here, a total dose G is prescribed for the entire X-ray exposure, which is in the dose measuring device 20 should come to mind. At this time, then the X-ray source 6 be switched off. The dose amount M is chosen here as a quarter of the total dose G. Thus generated at times t _z, in each of which a quarter, a half, three-quarters full and the total dose G are sunken, the X-ray detector 8th a respective count pulse 24 , The resulting transmission signal T is in the basic unit 4 evaluated and so at time t _1, the X-ray source 6 be switched off.

4 shows a further alternative of a transmission signal T. Here forms the X-ray detector 8th continuously a sum value 26 in the dose measuring device 20 incident X-ray dose D, during operation of the X-ray source 6 increases steadily from the time t ₀ . For the sum value 26 there is a limit 28 , Again, the X-ray source 6 after a processing of the transmission signal T in the X-ray system 2 then switched off when a total dose G is reached, which is represented by the limit G or is correlated with this. The transmission signal T includes the sum value 26 that is, on exceeding a limit 28 is monitored, then the X-ray source 6 off.

Although the invention has been further illustrated and described in detail by the preferred embodiment, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

LIST OF REFERENCE NUMBERS

2

 X-ray system

4

 basic unit

6

 X-ray source

8th

 X-ray detector

10

 payload

12

 radio link

14

 image system

16

 WLAN access point

18

 connection

20

 Dose measuring device

22

 radio link

24

 count pulse

26

 total value

28

 limit

S

 signal

D

 X-ray dose

T

 send signal

M

 dose level

G

 total dose

t, t ₀ , t ₁

 Time

t _z

 time

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• IEEE standard 802.11an [0002]

Claims (6)

Method for operating an X-ray system ( 2 ) with a basic device ( 4 ) with an X-ray source ( 6 ), and with a portable wireless X-ray detector ( 8th ), in which - the X-ray detector ( 8th ) non-time-critical payload data ( 10 ) via a synchronous radio link ( 12 ) with the basic device ( 4 ), - a dose measuring device ( 20 ) in the X-ray detector ( 8th ) generates a time-critical signal (S) correlated with an incident x-ray dose (D), - the x-ray detector ( 8th ) the signal (S) in the form of a transmission signal (T) via an asynchronous radio link ( 22 ) to the basic device ( 4 ) transmits, - the X-ray system ( 2 ) is operated depending on the signal (S). Method according to Claim 1, in which the x-ray detector ( 8th ) as a transmission signal (T) a sequence of a respective dose amount (M) of the X-ray dose (D) associated counting pulses ( 24 ) generated. The method of claim 2, wherein the dose amount (M) corresponds to a value of a single X-ray quantum. Method according to Claim 2, in which the dose quantity (M) corresponds to a value correlated with a predeterminable total dose (G). Method according to one of the preceding claims, in which the x-ray detector ( 8th ) as the transmission signal (T) continuously a sum value ( 26 ) forms the X-ray dose (D), and continuously transmits the transmission signal (T). Method according to one of the preceding claims, in which the X-ray system ( 2 ) is operated on the basis of the transmission signal (T) such that the basic device ( 4 ) from the transmission signal (T) a sum value ( 26 ) of the X-ray dose (D) and the X-ray source ( 6 ) then turns off when the sum value ( 26 ) a limit ( 28 ) reached.

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