Apparatus and Method for Detecting Presence of Attenuation in OLED Device

Abstract

An apparatus and a method for detecting presence of attenuation in the OLED device are provided. The apparatus for detecting presence of attenuation in the OLED device includes: a difference function construction circuit, an integrating circuit, a comparing circuit and a determining circuit. The method for detecting presence of attenuation in the OLED device includes: constructing a first light brightness difference function and a second light brightness difference function before and after aging, integrating the first function and the second function, comparing two integrals, and determining whether or not intrinsic attenuation is present in a light emitting material of a light emitting layer in the OLED device. The apparatus for detecting presence of attenuation in the OLED device is configured for executing the method for detecting presence of attenuation in the OLED device.

Description

TECHNICAL FIELD

Embodiments of the present disclosure relate to a field of display technology, and more particularly, to an apparatus for detecting presence of attenuation in an OLED device and a method for the same.

BACKGROUND

An organic light emitting display (OLED) device is a type of active light-emitting display device, which, as compared with a liquid crystal display, has advantages of faster response, higher contrast, wider viewing angle, and so on, and draws people's more attention.

In an OLED device, each OLED circuit includes an anode layer, a cathode layer and an organic layer provided between the anode layer and the cathode layer. The organic layer includes an electron transport layer and a hole transport layer, and a light emitting layer located between the electron transport layer and the hole transport layer. In the OLED devices such as the OLED displays, attenuation will occur to the organic layer with increase of usage time, which greatly affects the service life of the OLED displays. Therefore, an apparatus and method for detecting the attenuation of the OLED devices is needed at present, which is capable of determining whether or not intrinsic attenuation is present in a light emitting material of the light emitting layer in the OLED devices.

SUMMARY

An objective of the present disclosure is to provide an apparatus for detecting presence of attenuation in an OLED device and a method for detecting presence of attenuation in an OLED device, in order to determine whether or not intrinsic attenuation is present in a light emitting material of a light emitting layer in the OLED device.

In first aspect of the disclosure, it is provided an apparatus for detecting presence of attenuation in an OLED device, comprising: a difference function construction circuit, configured for constructing a first light brightness difference function ƒ₁(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, before aging of the OLED device; constructing a second light brightness difference function ƒ₂(x), according to a difference between light brightness of the OLED device under the first luminous constraint and light brightness of the OLED device under the second luminous constraint, after aging of the OLED device; wherein, the first luminous constraint comprises a variable magnetic field, the second luminous constraint comprises a constant microwave and a variable magnetic field, and x is an intensity of the variable magnetic field; an integrating circuit, configured for integrating the first light brightness difference function ƒ₁(x), to obtain a first integration result Ena, and integrating the second light brightness difference function ƒ₂(x), to obtain a second integration result Ea, within an intensity range of the variable magnetic field; a comparing circuit, configured for comparing

$\frac{\mathrm{La}}{\mathrm{Ea}}\mathrm{with}\frac{\mathrm{Lna}}{\mathrm{Ena}};$

wherein, Lna is light brightness of a pre-aging OLED device under a non-luminous constraint, and La is light brightness of a post-aging OLED device under the non-luminous constraint; and a determining circuit, configured for determining the presence of intrinsic attenuation in a light emitting material of a light emitting layer in the OLED device, according to a comparison result between

$\frac{\mathrm{La}}{\mathrm{Ea}}\mathrm{and}\frac{\mathrm{Lna}}{\mathrm{Ena}}.$

In second aspect of the disclosure, it is provided a method for detecting presence of attenuation in an OLED device, comprising: constructing a first light brightness difference function ƒ₁(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, before aging of the OLED device; constructing a second light brightness difference function ƒ₂(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, after aging of the OLED device; wherein the first luminous constraint comprises a constant microwave and a variable magnetic field, and x is an intensity of the variable magnetic field; integrating the first light brightness difference function ƒ₁(x), to obtain a first integration result Ena, and integrating the second light brightness difference function ƒ₂(x), to obtain a second integration result Ea, within an intensity range of the variable magnetic field; comparing

$\frac{\mathrm{La}}{\mathrm{Ea}}\mathrm{with}\frac{\mathrm{Lna}}{\mathrm{Ena}};$

wherein, Lna is light brightness of a pre-aging OLED device under a non-luminous constraint, and La is light brightness of a post-aging OLED device under the non-luminous constraint; and determining the presence of intrinsic attenuation in a light emitting material of a light emitting layer in the OLED device, according to a comparison result between

$\frac{\mathrm{La}}{\mathrm{Ea}}\mathrm{and}\frac{\mathrm{Lna}}{\mathrm{Ena}}.$

BRIEF DESCRIPTION OF THE DRAWINGS

In order to clearly illustrate the technical solution of the embodiments of the disclosure, the drawings of the embodiments will be briefly described in the following; it is obvious that the described drawings are only related to some embodiments of the disclosure and thus are not limitative of the disclosure.

FIG. 1 is a block diagram of an apparatus for detecting presence of attenuation in an OLED device provided by an embodiment of the present disclosure;

FIG. 2 is a block diagram of a function construction circuit provided by an embodiment of the present disclosure;

FIG. 3 is a function graph constructed by an apparatus for detecting presence of attenuation in an OLED device provided by an embodiment of the present disclosure under two various luminous constraints;

FIG. 4 is a graph of a difference function constructed by an apparatus for detecting presence of attenuation in an OLED device provided by an embodiment of the present disclosure;

FIG. 5 is a structural schematic diagram of an OLED light brightness measuring member in an apparatus for detecting presence of attenuation in an OLED device provided by an embodiment of the present disclosure;

FIG. 6 is a flow chart of a method for detecting presence of attenuation in an OLED device provided by an embodiment of the present disclosure;

FIG. 7 is a flow chart of a pre-aging light brightness difference function ƒ₁(x) constructed in a method for detecting presence of attenuation in an OLED device provided by an embodiment of the present disclosure;

FIG. 8 is a flow chart of a second light brightness difference function ƒ₂(x) constructed in a method for detecting presence of attenuation in an OLED device provided by the embodiment of the present disclosure;

FIG. 9 is a flow chart of determining whether or not aging occurs to the OLED device in a method for detecting presence of attenuation in an OLED device provided by an embodiment of the present disclosure.

DETAILED DESCRIPTION

In order to make objects, technical details and advantages of the embodiments of the disclosure apparent, the technical solutions of the embodiments will be described in a clearly and fully understandable way in connection with the drawings related to the embodiments of the disclosure. Apparently, the described embodiments are just a part but not all of the embodiments of the disclosure. Based on the described embodiments herein, those skilled in the art can obtain other embodiment(s), without any inventive work, which should be within the scope of the disclosure.

With reference to FIG. 1 and FIG. 6, an apparatus for detecting presence of attenuation in an OLED device provided by an embodiment of the present disclosure comprises: a difference function construction circuit 200, an integrating circuit 300, a comparing circuit 400 and a determining circuit 500. The difference function construction circuit 200 is configured for constructing a pre-aging light brightness difference function ƒ₁(x) (i.e., a first light brightness difference function), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, before aging of the OLED device; constructing a post-aging light brightness difference function ƒ₂(x) (i.e., a second light brightness difference function), according to a difference between light brightness of the OLED device under the first luminous constraint and light brightness of the OLED device under the second luminous constraint, after aging of the OLED device. The first luminous constraint is a single constraint environment, and the single constraint environment is a variable magnetic field; the second luminous constraint is a dual constraint environment, the dual constraint environment includes a constant microwave and a variable magnetic field, and x is an intensity of the variable magnetic field.

The integrating circuit 300 is configured for integrating the pre-aging light brightness difference function ƒ₁(x), to obtain a first integration result Ena, and integrating the second light brightness difference function ƒ₂(x), to obtain a second integration result Ea, within an intensity range of the variable magnetic field.

The comparing circuit 400 is configured for comparing

$\frac{\mathrm{La}}{\mathrm{Ea}}\mathrm{with}\frac{\mathrm{Lna}}{\mathrm{Ena}};$

wherein, Lna is light brightness of a pre-aging OLED device under a non-luminous constraint, and La is light brightness of a post-aging OLED device under the non-luminous constraint. The “non-luminous constraint” here refers to the luminous constraint which is different from the first luminous constraint and the second luminous constraint, for example, it refers to a constant current or a constant voltage.

The determining circuit 500 is configured for determining whether or not intrinsic attenuation is present in a light emitting material of a light emitting layer in the OLED device, according to a comparison result between

$\frac{\mathrm{La}}{\mathrm{Ea}}\mathrm{and}\frac{\mathrm{Lna}}{\mathrm{Ena}}.$

As an example, if

$\frac{\mathrm{La}}{\mathrm{Ea}}\ge \frac{\mathrm{Lna}}{\mathrm{Ena}},$

the determining circuit 500 determines that intrinsic attenuation is non-present in the light emitting material of the light emitting layer in the OLED device; if

$\frac{\mathrm{La}}{\mathrm{Ea}}<\frac{\mathrm{Lna}}{\mathrm{Ena}},$

it determines that intrinsic attenuation is present in the light emitting material of the light emitting layer in the OLED device.

In at least some of embodiments, the apparatus for detecting presence of attenuation in the OLED device provided by the above-described embodiment is configured to analyze the OLED device before aging, and the analyzing process comprises:

before the aging of the OLED device, constructing, by the difference function construction circuit 200, the pre-aging light brightness difference function ƒ₁(x), according to the difference between the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint;

integrating, by the integrating circuit 300, the pre-aging light brightness difference function ƒ₁(x), within the intensity range of the variable magnetic field, to obtain the first integration result Ena.

In at least some of embodiments, the apparatus for detecting presence of attenuation in the OLED device provided by the above-described embodiment is configured to analyze the OLED device after aging, and the analyzing process comprises:

after the aging of the OLED device, constructing, by the difference function construction circuit 200, the second light brightness difference function ƒ₂ (x), according to the difference between the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint;

integrating, by the integrating circuit 300, the second light brightness difference function ƒ₂ (x), within the intensity range of the variable magnetic field, to obtain the first integration result Ea.

In at least some of embodiments, after the above-described analysis is performed on the pre-aging and the post-aging OLED device with the apparatus for detecting presence of attenuation in the OLED device, the comparing circuit 400 compares

$\frac{\mathrm{La}}{\mathrm{Ea}}\mathrm{with}\frac{\mathrm{Lna}}{\mathrm{Ena}},$

and then the determining circuit 500 determines whether or not intrinsic attenuation is present in the light emitting material of the light emitting layer in the OLED device, according to the comparison result between

$\frac{\mathrm{La}}{\mathrm{Ea}}\mathrm{and}\frac{\mathrm{Lna}}{\mathrm{Ena}}.$

As an example, if

$\frac{\mathrm{La}}{\mathrm{Ea}}\ge \frac{\mathrm{Lna}}{\mathrm{Ena}},$

it is determined that intrinsic attenuation is non-present in the light emitting material of the light emitting layer in the OLED device; if

$\frac{\mathrm{La}}{\mathrm{Ea}}<\frac{\mathrm{Lna}}{\mathrm{Ena}},$

it is determined that intrinsic attenuation is present in the light emitting material of the light emitting layer in the OLED device, other than that attenuation is present in an electron transport layer, a hole transport layer, a layer interface, or other parts.

In the OLED device provided by the embodiment of the present disclosure, the first luminous constraint is the single constraint environment of the variable magnetic field, so that electrons and holes for forming excitons in both the pre-aging OLED device and the post-aging OLED device are capable of responding to change in the intensity of the magnetic field (as shown by curve b in FIG. 3), so as to emit light of different luminance. The second luminous constraint is the dual constraint environment of the constant microwave and the variable magnetic field, so that both the electrons and the holes for forming the excitons in both the pre-aging OLED device and the post-aging OLED device are capable of not only responding to change in the intensity of the magnetic field so as to emit light of different luminance, but also making sudden change to the light brightness within a certain intensity range (as shown by curve a in FIG. 3) under an effect of the constant microwave. In this way, in the apparatus for detecting presence of attenuation in the OLED device provided by the embodiment of the present disclosure, by constructing the first light brightness difference function ƒ₁(x) and the second light brightness difference function ƒ₂(x), according to the difference between the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint, before and after aging of the OLED device, and by integrating the same within the intensity range of the variable magnetic field, the first integration result Ena characterizing the number of excitons in the pre-aging OLED device, and the second integration result Ea characterizing the number of excitons in the post-aging OLED device may be obtained. FIG. 4 illustrates a curve graph of a difference function. However, considering the intrinsic attenuation of the light-emitting material in the light-emitting layer of the OLED device, the probability of the radiation transition present in the light-emitting layer in the OLED device decreases relative to that of the non-radiation transition, and the light emission brightness of the OLED device can characterize the probability of the radiation transition, it is possible to compare a ratio

$\frac{\mathrm{Lna}}{\mathrm{Ena}}$

of the pre-aging OLED device with a ratio

$\frac{\mathrm{La}}{\mathrm{Ea}}$

of the post-aging OLED device, so as to determine whether or not intrinsic attenuation is present in the light emitting material of the light emitting layer in the OLED device.

Under the second luminous constraint, both the electrons and the holes for forming the excitons in both the pre-aging OLED device and the post-aging OLED device are capable of making sudden change to the light brightness within a certain intensity range due to the effect of the constant microwave, this is because of that under the dual constraint environment of the constant microwave and the variable magnetic field of the second luminous constraint, the electrons and the holes for forming the excitons in the OLED device generate resonance response, so that sudden change occurs to the light brightness of the OLED device within a certain intensity range.

It can be understood that, after formation of the excitons in the OLED device, there is radiation transition kp and non-radiation transition knp, the radiation transition kp will emit photons, and the corresponding non-radiation transition knp will generate heat in the device to be diffused. If the light emitting material contained in the light emitting layer in the OLED device is deteriorated, the probability of the non-radiation transition knp will increase relative to the probability of the radiation transition kp, so that the light brightness of the OLED device is reduced, that is, the light brightness of the OLED device may characterize the probability of the radiation transition.

It should be noted that, in the above-described embodiment, a microwave frequency of the constant microwave is from 10 GHz to 20 GHz, for example, 10 GHz, 20 GHz, or 15 GHz, and the intensity range of the variable magnetic field is from 0 mT to 500 mT, and both of them may be selected according to an actual situation.

In order to improve accuracy of attenuation detection of the OLED device, the pre-aging OLED device and the post-aging OLED device are a same OLED device, so after the above-described analysis is performed on the pre-aging OLED device with the apparatus for detecting presence of attenuation in the OLED device, aging process is performed on the OLED device, and then the above-described analysis is performed on the pre-aging and the post-aging OLED device with the apparatus for detecting presence of attenuation in the OLED device.

It can be understood that, the pre-aging OLED device and the post-aging OLED device are OLED devices of a same type and a same batch, that is, the above-described analysis may be performed on the pre-aging OLED device with the apparatus for detecting presence of attenuation in the OLED device firstly, or the above-described analysis may also be performed on the post-aging OLED device with the apparatus for detecting presence of attenuation in the OLED device firstly; however, due to individual difference, accuracy of attenuation analysis of the OLED device may be affected.

In at least some of embodiments, with reference to FIG. 2, FIG. 7 and FIG. 8, the difference function construction circuit 200 in the above-described embodiment comprises a function constructing sub-circuit 201 and a difference operating sub-circuit 202 connected with an output terminal of the function constructing sub-circuit 201; and the output terminal of the difference operating sub-circuit 202 is connected with an input terminal of the integrating circuit 300.

The function construction sub-circuit 201 is configured for storing the intensity of the variable magnetic field, constructing a first pre-aging light brightness function ƒ₁₁(x) characterizing a first pre-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the first luminous constraint before aging of the OLED device, and constructing a second pre-aging light brightness function ƒ₂₁(x) characterizing a second pre-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the second luminous constraint after aging of the OLED device, and constructing a first post-aging light brightness function ƒ₁₂(x) characterizing a first post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the first luminous constraint after aging of the OLED device, and constructing a second post-aging light brightness function ƒ₂₂(x) characterizing a second post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the second luminous constraint after aging of the OLED device.

The difference operating sub-circuit 202 is configured for constructing the first light brightness difference function ƒ₁(x), according to the first pre-aging light brightness function ƒ₁₁(x) and the second pre-aging light brightness function ƒ₂₁(x); and constructing the second light brightness difference function ƒ₂(x), according to the first post-aging light brightness function ƒ₁₂(x) and the second post-aging light brightness function ƒ₂₂(x); wherein, ƒ₁(x)=|ƒ₁₁(x)−ƒ₂₁(x)|, ƒ₂(x)=|ƒ₁₂(x)−ƒ₂₂(x)|.

In at least some of embodiments, with reference to FIG. 7, the function construction circuit 200 constructs the first light brightness difference function ƒ₁(x) by using a method below:

before aging of the OLED device, constructing, by the function constructing sub-circuit 201, the first pre-aging light brightness function ƒ₁₁(x) characterizing the first pre-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the first luminous constraint;

before aging of the OLED device, constructing, by the function constructing sub-circuit 201, the second pre-aging light brightness function ƒ₂₁(x) characterizing the second pre-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the second luminous constraint;

constructing, by the difference operating sub-circuit 202, the first light brightness difference function ƒ₁(x), according to the first pre-aging light brightness function ƒ₁₁(x) and the second pre-aging light brightness function ƒ₂₁(x); wherein, ƒ₁(x)=|ƒ₁₁(x)−ƒ₂₁(x)|.

With reference to FIG. 8, the function construction circuit 200 constructs the second light brightness difference function ƒ₂ (x) by using a method below:

after aging of the OLED device, constructing, by the function constructing sub-circuit 201, the first post-aging light brightness function ƒ₁₂(x) characterizing the first post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the first luminous constraint;

after aging of the OLED device, constructing, by the function constructing sub-circuit 201, the second post-aging light brightness function ƒ₂₂(x) characterizing the second post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the second luminous constraint;

Constructing, by the difference operating sub-circuit 202, the second light brightness difference function ƒ₂(x), according to the first post-aging light brightness function ƒ₁₂(x) and the second post-aging light brightness function ƒ₂₂(x); wherein, ƒ₂(x)=|ƒ₁₂(x)−ƒ₂₂(x)|.

Curve b of FIG. 3 shows the light brightness corresponding to the OLED device under the first luminous constraint.

Curve a of FIG. 3 shows the light brightness curve corresponding to the OLED device under the second luminous constraint.

By comparing curve a and curve b, it can be found that, under the first luminous constraint, the light brightness curve of the OLED device is relatively stable, and as the intensity increases, the light brightness of the OLED device gradually increases. Under the second luminous constraint, due to the effect of the dual constraint environment of the constant microwave and the variable magnetic field, the electrons and the holes for forming the excitons in the light emitting material are capable of not only responding to change in the intensity, but also making sudden change to the light brightness of the OLED device within a certain intensity range, under the effect of the constant microwave.

It can be known from specific processes of constructing the first light brightness difference function ƒ₁(x) and constructing the second light brightness difference function ƒ₂(x) in the above-described embodiment, regardless whether before aging of the OLED device or after aging of the OLED device, in the embodiment of the present disclosure, the function under the first luminous constraint and the second luminous constraint function are always obtained firstly, and then the two functions are subtracted to obtain the corresponding difference function. As a result, in the embodiment of the present disclosure, by taking advantage of difference between responses of the electrons and the holes forming the excitons in the OLED device to the first luminous constraint and the second luminous constraint, the difference function which can reflect the number of the excitons is obtained, and by performing finite integration on the difference function, the obtained integration result is capable of characterizing the number of excitons in the OLED device.

In at least some of embodiments, the apparatus for detecting presence of attenuation in the OLED device provided by the above-described embodiment further comprises a data obtaining circuit 100, an output terminal of the data obtaining circuit 100 being respectively connected with an input terminal of the difference function construction circuit 200 and an input terminal of the comparing circuit 400, with reference to FIG. 1 and FIG. 9.

As an example, the output terminal of the data obtaining circuit 100 is connected with an input terminal of the function constructing sub-circuit 201. The data obtaining circuit 100 is configured for obtaining the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint, before aging of the OLED device; and obtaining the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint, after aging of the OLED device.

As an example, the data obtaining circuit 100 is further configured for obtaining the light brightness Lna of the pre-aging OLED device under the non-luminous constraint and the light brightness La of the post-aging OLED device under the non-luminous constraint. In this case, the comparing circuit 400 is further configured for storing the light brightness Lna of the pre-aging OLED device and the light brightness La of the post-aging OLED device under the non-luminous constraint, and comparing Lna with La. The determining circuit 500 is further configured for determining whether or not aging occurs to the OLED device, according to the comparison result between Lna and La. The above-described step of determining whether or not aging occurs to the OLED device may be executed simultaneously with the determining whether or not intrinsic attenuation is present in the light emitting material of the light emitting layer in the OLED device; or, may be executed thereafter, so that it is possible to further verify the result thereof.

In at least some of embodiments, in addition to obtaining the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint, before aging of the OLED device, the data obtaining circuit 100 is further configured for obtaining the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint, after aging of the OLED device, and is further configured for obtaining the light brightness Lna of the pre-aging OLED device under the non-luminous constraint and the light brightness La of the post-aging OLED device under the non-luminous constraint.

The comparing circuit 400 stores the light brightness Lna of the pre-aging OLED device under the non-luminous constraint and the light brightness La of the post-aging OLED device under the non-luminous constraint, and compares Lna with La;

The determining circuit 500 determines whether or not aging occurs to the OLED device, according to the comparison result between Lna and La.

By connecting the output terminal of the data obtaining circuit 100 with the input terminal of the comparing circuit 400, the apparatus for detecting presence of attenuation in the OLED device provided by the embodiment of the present disclosure is capable of obtaining, with the data obtaining circuit 100, the light brightness of the pre-aging and the post-aging OLED device, under the non-luminous constraint, and determining whether aging actually occurs by using the comparing circuit 400 and the determining circuit 500; in addition, it is also capable of storing the light brightness of the pre-aging and the post-aging OLED device both under the non-luminous constraint, by the comparing circuit, so as to participate in determining whether or not intrinsic attenuation occurs to the light emitting material of the light emitting layer in the OLED device.

If La<Lna, the determining circuit 500 determines that aging occurs to the OLED device; and if La=Lna, it determines that aging does not occur to the OLED device.

It should be noted that, as an example, the data obtaining circuit 100 obtains the light brightness of the OLED device by using an OLED light brightness measuring member as shown in FIG. 5. The OLED light brightness measuring member comprises a magnetic field generating member 2, a microwave generating member 1 and an optical measuring member 3. An output terminal of the optical measuring member 3 is connected with the data obtaining circuit 100. The magnetic field generating member 2 is configured for providing a variable magnetic field for the OLED device. The microwave generating member 1 is configured for providing a constant microwave for the OLED device. The microwave generating member, for example, may be implemented by a common microwave generator, which is capable of providing a microwave of a constant wavelength. The optical measuring member 3 is configured for measuring the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint before and after aging of the OLED device; and/or, measuring the light brightness of the OLED device under the non-luminous constraint, before and after aging of the OLED device. For example, the optical measuring apparatus may be an optical power meter or a photomultiplier tube, and may also be other apparatuses capable of measuring the light luminance.

It can be understood that, in order to facilitate the OLED device to emit light, a power supply for supplying power to the OLED device may be further provided, so that the OLED light brightness measuring member may work independently; and the power supply may be a high precision source meter, for example, keithley2400, so as to ensure supply of the constant current or the constant voltage to the OLED device, so that the OLED device will not be affected by the magnetic field and microwave and other factors.

In respective times of measurement by the OLED light brightness measuring member, the relationship between the OLED device and detecting conditions is listed in a table below.

Table 1 relationship between OLED device and detecting conditions in respective times of measurement

OLED device state      Detecting conditions
Pre-aging OLED device  Non-luminous constraint
Post-aging OLED device Non-luminous constraint
Pre-aging OLED device  First luminous constraint
Pre-aging OLED device  Second luminous constraint
Post-aging OLED device First luminous constraint
Post-aging OLED device Second luminous constraint

For example, the magnetic field generating member 2 in the above-described embodiment is a controllable excitation power supply; a microwave stage 11 for carrying an OLED device 4 is provided in a magnetic field environment provided by the controllable excitation power supply; a transmitting terminal of the microwave generating member 1 is connected with the microwave stage 11 through a waveguide tube 10. The optical measuring member 3 collects light emitted by the OLED device through an optical fiber 30.

Because the magnetic field generating member is the controllable excitation power supply, it is ensured that the variable magnetic field can be supplied to the OLED device, so that the OLED device can emit light with different luminance in response to different magnetic field intensities.

Moreover, since the microwave stage 11 is capable of carrying the OLED device, and the transmitting terminal of the microwave generating member 1 is connected with the microwave stage 11 through the waveguide tube 10, the microwave stage 11 is also equivalent to an injecting circuit for injecting a constant microwave into the OLED device, and the microwave stage 11 is located in the variable magnetic field.

It should be noted that, ranges of the microwave wavelength and the intensity in the above-described embodiments are specifically selected. For example, the microwave generator provides a microwave at any frequency of 10 GHz to 20 GHz, for example, 10 GHz, 13 GHz, or 20 GHz. The intensity range of the variable magnetic field is from 0 mT to 500 mT.

With reference to FIG. 6, another embodiment of the present disclosure provides a method for detecting presence of attenuation in the OLED device of an OLED device, comprising:

constructing a first light brightness difference function ƒ₁(x), according to difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, before aging of the OLED device; constructing a second light brightness difference function ƒ₂(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, after aging of the OLED device; wherein, the first luminous constraint is a single constraint environment, the single constraint environment is a variable magnetic field, the second luminous constraint is a dual constraint environment, the dual constraint environment includes a constant microwave and a variable magnetic field, and x is an intensity of the variable magnetic field;

integrating the first light brightness difference function ƒ₁(x), to obtain a first integration result Ena, and integrating the second light brightness difference function ƒ₂(x), to obtain a second integration result Ea, within an intensity range of the variable magnetic field;

comparing

$\frac{\mathrm{La}}{\mathrm{Ea}}\mathrm{with}\frac{\mathrm{Lna}}{\mathrm{Ena}};$

wherein, Lna is light brightness of a pre-aging OLED device under a non-luminous constraint, and La is light brightness of a post-aging OLED device under the non-luminous constraint;

determining whether or not intrinsic attenuation is present in a light emitting material of a light emitting layer in the OLED device, according to a comparison result between

$\frac{\mathrm{La}}{\mathrm{Ea}}\mathrm{and}\frac{\mathrm{Lna}}{\mathrm{Ena}}.$

The method for detecting presence of attenuation in the OLED device provided by the embodiment of the present disclosure has advantageous effects the same as the advantageous effects of the apparatus for detecting presence of attenuation in the OLED device provided by the above-mentioned embodiment, so the advantageous effects will not be repeated here.

As an example, before constructing the first light brightness difference function ƒ₁(x) and the second light brightness difference function ƒ₂(x) in the above-described embodiment, the light brightnesses of the OLED device under the first and second luminous constraints before aging of the OLED device and the light brightnesses of the OLED device under the first and second luminous constraints after aging of the OLED device are both obtained.

In at least some of embodiments, the process for determining whether or not intrinsic attenuation is present in a light emitting material of a light emitting layer in the OLED device, according to a comparison result between comprises:

$\frac{\mathrm{La}}{\mathrm{Ea}}\mathrm{and}\frac{\mathrm{Lna}}{\mathrm{Ena}},$

determining that intrinsic attenuation is non-present in the light emitting material of the light emitting layer in the OLED device, if

$\frac{\mathrm{La}}{\mathrm{Ea}}\ge \frac{\mathrm{Lna}}{\mathrm{Ena}};$

determining that intrinsic attenuation is present in the light emitting material of the light emitting layer in the OLED device, if

$\frac{\mathrm{La}}{\mathrm{Ea}}<\frac{\mathrm{Lna}}{\mathrm{Ena}}.$

It should be noted that, ranges of the microwave wavelength and the intensity in the above-described embodiments are specifically selected. For example, the microwave generator provides microwaves at any frequency of 10 GHz to 20 GHz, for example, 10 GHz, 13 GHz, or 20 GHz. The intensity range of the variable magnetic field is from 0 mT to 500 mT.

In at least some of embodiments, with reference to FIG. 7, the process for constructing a first light brightness difference function ƒ₁(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, before aging of the OLED device, comprises:

constructing a first pre-aging light brightness function ƒ₁₁(x) characterizing a first pre-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the first luminous constraint before aging of the OLED device;

constructing a second pre-aging light brightness function ƒ₂₁(x) characterizing a second pre-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the second luminous constraint before aging of the OLED device;

constructing the first light brightness difference function ƒ₁(x), according to the first pre-aging light brightness function ƒ₁₁(x) and the second pre-aging light brightness function ƒ₂₁(x); wherein, ƒ₁(x)=|ƒ₁₁(x)−ƒ₂₁(x)|.

In at least some of embodiments, with reference to FIG. 8, the process for constructing a second light brightness difference function ƒ₂(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, after aging of the OLED device, comprises:

constructing a first post-aging light brightness function ƒ₁₂(x) characterizing a first post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the first luminous constraint after aging of the OLED device, and constructing a second post-aging light brightness function ƒ₂₂(x) characterizing a second post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the second luminous constraint after aging of the OLED device;

constructing the second light brightness difference function ƒ₂(x), according to the first post-aging light brightness function ƒ₁₂(x) and the second post-aging light brightness function ƒ₂₂(x); wherein, ƒ₂(x)=|ƒ₁₂(x)−ƒ₂₂(x)|.

In at least some of embodiments, with reference to FIG. 9, the method for detecting presence of attenuation in the OLED device provided by the above-described embodiment further comprises:

obtaining light brightness Lna of the pre-aging OLED device under the non-luminous constraint and light brightness La of the post-aging OLED device under the non-luminous constraint;

storing the light brightness Lna of the pre-aging OLED device and the light brightness La of the post-aging OLED device, and comparing Lna with La; and

determining whether or not aging occurs to the OLED device, according to a comparison result between Lna and La.

The above-described process of determining whether or not aging occurs to the OLED device may be executed simultaneously with the determining whether or not intrinsic attenuation is present in the light emitting material of the light emitting layer in the OLED device; or, may be executed after the determining whether or not intrinsic attenuation is present in the light emitting material of the light emitting layer in the OLED device, to further verify the result thereof.

In at least some of embodiments, the process for determining whether or not aging occurs to the OLED device, according to a comparison result between Lna and La, comprises:

determining that aging occurs to the OLED device, if La<Lna; and determining that aging does not occur to the OLED device, if La=Lna.

In the apparatus and the method for detecting presence of attenuation in the OLED device provided by the embodiments of the present disclosure, the first luminous constraint is the single constraint environment of the variable magnetic field, so that regardless whether in the pre-aging OLED device or in the post-aging OLED device, both the electrons and the holes for forming the excitons are capable of responding to change in the intensity, to emit light of different luminance; and the second luminous constraint is the dual constraint environment of the constant microwave and the variable magnetic field, so that regardless whether in the pre-aging OLED device or in the post-aging OLED device, both the electrons and the holes for forming the excitons are capable of not only responding to change in the intensity, but also making sudden change to the light brightness within a certain intensity range, under the effect of the constant microwave. In this way, by constructing, with the difference function construction circuit, the first light brightness difference function ƒ₁(x) and the second light brightness difference function ƒ₂(x), according to the difference between the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint, before and after aging of the OLED device, and by integrating the same within the intensity range of the variable magnetic field, the first integration result Ena characterizing the number of excitons in the pre-aging OLED device, and the second integration result Ea characterizing the number of excitons in the post-aging OLED device may be obtained; however, considering the intrinsic attenuation of the light-emitting material in the light-emitting layer of the OLED device, the probability of the radiation transition present in the light-emitting layer in the OLED device decreases relative to that of the non-radiation transition, and the light emission brightness of the OLED device can characterize the probability of the radiation transition, it is possible to compare a ratio

$\frac{\mathrm{Lna}}{\mathrm{Ena}}$

of the pre-aging OLED device with a ratio

$\frac{\mathrm{La}}{\mathrm{Ea}}$

of the post-aging OLED device, so as to determine whether or not intrinsic attenuation is present in the light emitting material of the light emitting layer in the OLED device.

Those skilled in the art shall understand that the embodiments of the disclosure are able to be provided as a method, a system or a computer program product. Therefore, the disclosure can adopt forms of a complete hardware embodiment, a complete software embodiment or embodiment combining software and hardware. In addition, the disclosure can adopt the form of computer program product that is implemented on one or more computer applicable storage mediums (comprising, but not limited, disk memory, CD-ROM, optical memory, etc.) comprising computer applicable program codes therein.

The disclosure is described herein with reference to flowchart charts and/or block diagrams of methods, apparatuses (systems), and computer program products according to the embodiments of the disclosure. It should be understood that each flow and/or block in the flowchart and/or block diagram, and a combination of flow and/or block in the flowchart and/or block diagram can be implemented by computer program instructions. These computer program instructions may be provided to a general purpose computer, a special purpose computer, an embedded processor or a processor of other programmable data processing apparatus to form a machine, such that devices for implementing functions specified by one or more flows in the flowchart and/or one or more blocks in the block diagram may be generated by executing the instructions with the processor of the computer or other programmable data processing apparatus.

These computer program instructions may also be stored in a computer-readable memory that can direct the computer or other programmable data processing apparatus to operate in a given manner, so that the instructions stored in the computer-readable memory produce a manufactured article comprising an instruction device, and the instruction device implements the functions specified by one or more flows in the flowchart and/or one or more blocks in the block diagram.

These computer program instructions may also be loaded onto the computer or other programmable data processing apparatus, such that a series of process steps may be executed on the computer or other programmable data processing apparatus to produce process implemented by the computer, thereby, the instructions executed on the computer or other programmable data processing apparatus provide steps of implementing the functions specified by one or more flows in the flowchart and/or one or more blocks in the block diagram.

What is described above is related to the illustrative embodiments of the disclosure only and not limitative to the scope of the disclosure; the scopes of the disclosure are defined by the accompanying claims.

This application claims priority of Chinese Patent Application No. 201610634740.X filed on Aug. 4, 2016, the disclosure of which is incorporated herein by reference in its entirety as part of the present application.

Claims

1. An apparatus for detecting presence of attenuation in an organic light emitting display (OLED) device, comprising: a difference function construction circuit, configured for constructing a first light brightness difference function ƒ1(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, before aging of the OLED device; constructing a second light brightness difference function ƒ2(x), according to a difference between light brightness of the OLED device under the first luminous constraint and light brightness of the OLED device under the second luminous constraint, after aging of the OLED device; wherein, the first luminous constraint comprises a variable magnetic field, the second luminous constraint comprises a constant microwave and a variable magnetic field, and x is an intensity of the variable magnetic field;an integrating circuit, configured for integrating the first light brightness difference function ƒ1(x), to obtain a first integration result Ena, and integrating the second light brightness difference function ƒ2(x), to obtain a second integration result Ea, within an intensity range of the variable magnetic field;a comparing circuit, configured for comparing

2. The apparatus according to claim 1, wherein the difference function construction circuit comprises a function constructing sub-circuit and a difference operating sub-circuit connected with an output terminal of the function constructing sub-circuit; and the output terminal of the difference operating sub-circuit is connected with an input terminal of the integrating circuit; the function constructing sub-circuit is configured for storing the intensity of the variable magnetic field, constructing a first pre-aging light brightness function ƒ11(x) characterizing a first pre-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the first luminous constraint before aging of the OLED device, and constructing a second pre-aging light brightness function ƒ21(x) characterizing a second pre-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the second luminous constraint before aging of the OLED device; constructing a first post-aging light brightness function ƒ12(x) characterizing a first post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the first luminous constraint after aging of the OLED device, and constructing a second post-aging light brightness function ƒ22(x) characterizing a second post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the second luminous constraint after aging of the OLED device;the difference operating sub-circuit is configured for constructing the first light brightness difference function ƒ1(x), according to the first pre-aging light brightness function ƒ11(x) and the second pre-aging light brightness function ƒ21(x); and constructing the second light brightness difference function ƒ2(x), according to the first post-aging light brightness function ƒ12(x) and the second post-aging light brightness function ƒ22(x); wherein, ƒ1(x)=|ƒ11(x)−ƒ21(x)|, ƒ2(x)=|ƒ12(x)−ƒ22(x)|.

3. The apparatus according to claim 1, wherein the determining circuit is configured for determining that intrinsic attenuation is non-present in the light emitting material of the light emitting layer in the OLED device, if

4. The apparatus according to claim 1, further comprising a data obtaining circuit, and an output terminal of the data obtaining circuit is respectively connected with an input terminal of the difference function construction circuit and an input terminal of the comparing circuit; the data obtaining circuit is configured for obtaining the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint, before and after aging of the OLED device; and further configured for obtaining light brightness Lna of the pre-aging OLED device under the non-luminous constraint and the light brightness La of the post-aging OLED device under the non-luminous constraint;the comparing circuit is configured for storing the light brightness Lna of the pre-aging OLED device under the non-luminous constraint and the light brightness La of the post-aging OLED device under the non-luminous constraint, and comparing Lna with La;the determining circuit is further configured for determining whether or not the aging occurs to the OLED device, according to the comparison result between Lna and La.

5. The apparatus according to claim 4, wherein the determining circuit is configured for determining that aging occurs to the OLED device, if La<Lna; and determining that aging does not occur to the OLED device, if La=Lna.

6. The apparatus according to claim 4, further comprising: a magnetic field generating member, a microwave generating member and an optical measuring member; an output terminal of the optical measuring member being connected with the data obtaining circuit; the magnetic field generating member is configured for providing a variable magnetic field for the OLED device;the microwave generating member is configured for providing a constant microwave for the OLED device;the optical measuring member is configured for measuring the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint, before and after aging of the OLED device; and, measuring the light brightness of the OLED device under the non-luminous constraint, before and after aging of the OLED device.

7. The apparatus according to claim 6, wherein the magnetic field generating member is a controllable excitation power supply; a microwave stage for carrying the OLED device is provided in a magnetic field provided by the controllable excitation power supply; a transmitting terminal of the microwave generating member is connected with the microwave stage through a waveguide tube.

8. The apparatus according to claim 6, wherein the optical measuring member is an optical power meter or a photomultiplier tube.

9. The apparatus according to claim 6, further comprising a power supply for supplying power for the OLED device.

10. The apparatus according to claim 1, wherein a microwave frequency of the constant microwave ranges from 10 GHz to 20 GHz, and the intensity of the variable magnetic field ranges from 0 mT to 500 mT.

11. A method for detecting presence of attenuation in an organic light emitting display (OLED) device, comprising: constructing a first light brightness difference function ƒ1(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, before aging of the OLED device; constructing a second light brightness difference function ƒ2(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, after aging of the OLED device; wherein the first luminous constraint comprises a constant microwave and a variable magnetic field, and x is an intensity of the variable magnetic field;integrating the first light brightness difference function ƒ1(x), to obtain a first integration result Ena, and integrating the second light brightness difference function ƒ2(x), to obtain a second integration result Ea, within an intensity range of the variable magnetic field;comparing

12. The method according to claim 11, wherein constructing a first light brightness difference function ƒ1(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, before aging of the OLED device, comprises: constructing a first pre-aging light brightness function ƒ11(x) characterizing a first pre-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the first luminous constraint before aging of the OLED device;constructing a second pre-aging light brightness function ƒ21(x) characterizing a second pre-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the second luminous constraint before aging of the OLED device;constructing the first light brightness difference function ƒ1(x), according to the first pre-aging light brightness function ƒ11(x) and the second pre-aging light brightness function ƒ21(x); wherein, ƒ1(x)=|ƒ11(x)−ƒ21(x)|.

13. The method according to claim 11, wherein the method for constructing a second light brightness difference function ƒ2(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, after aging of the OLED device, comprises: constructing a first post-aging light brightness function ƒ12(x) characterizing a first post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the first luminous constraint after aging of the OLED device, and constructing a second post-aging light brightness function ƒ22(x) characterizing a second post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the second luminous constraint after aging of the OLED device;constructing the second light brightness difference function ƒ2(x), according to the first post-aging light brightness function ƒ12(x) and the second post-aging light brightness function ƒ22(x); wherein, ƒ2(x)=|ƒ12(x)−ƒ22(x)|.

14. The method according to claim 11, wherein determining the presence of intrinsic attenuation in a light emitting material of a light emitting layer in the OLED device, according to a comparison result between

15. The method according to claim 11, further comprising: obtaining the light brightness of the OLED device under the first luminous constraint and the light brightness of the OLED device under the second luminous constraint, before and after aging of the OLED device; and obtaining light brightness Lna of the pre-aging OLED device under the non-luminous constraint and the light brightness La of the post-aging OLED device under the non-luminous constraint;storing the light brightness Lna of the pre-aging OLED device under the non-luminous constraint and the light brightness La of the post-aging OLED device under the non-luminous constraint, and comparing Lna with La;determining whether or not the aging occurs to the OLED device, according to the comparison result between Lna and La.

16. The method according to claim 15, wherein determining whether or not aging occurs to the OLED device, according to the comparison result between Lna and La comprises: determining that aging occurs to the OLED device, if La<Lna; and determining that aging does not occur to the OLED device, if La=Lna.

17. The method according to claim 11, wherein the intensity of the variable magnetic field ranges from 0 mT to 500 mT, and a microwave frequency of the constant microwave ranges from 10 GHz to 20 GHz.

18. The apparatus according to claim 2, wherein the determining circuit is configured for determining that intrinsic attenuation is non-present in the light emitting material of the light emitting layer in the OLED device, if

19. The method according to claim 12, wherein the method for constructing a second light brightness difference function ƒ2(x), according to a difference between light brightness of the OLED device under a first luminous constraint and light brightness of the OLED device under a second luminous constraint, after aging of the OLED device, comprises: constructing a first post-aging light brightness function ƒ12(x) characterizing a first post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the first luminous constraint after aging of the OLED device, and constructing a second post-aging light brightness function ƒ22(x) characterizing a second post-aging light brightness curve, according to the intensity of the variable magnetic field and the light brightness of the OLED device under the second luminous constraint after aging of the OLED device;constructing the second light brightness difference function ƒ2(x), according to the first post-aging light brightness function ƒ12(x) and the second post-aging light brightness function ƒ22(x); wherein, ƒ2(x)=|ƒ12(x)−ƒ22(x)|.