Title of Invention	TESTING ADAPTER
Abstract	The invention relates to a testing adapter suitable for testing a wireless telecommunication device. The testing adapter comprises a first contact member (102A) and a second contact member (102B), the first contact member (102A) and the second contact member (102B) having at least one degree of freedom relative to each other and arranged to provide an attachable and detachable mechanical coupling with a surface of a component recess of the wireless telecommunication device on the basis of the at least one degree of freedom.

Title of Invention

TESTING ADAPTER

Abstract

The invention relates to a testing adapter suitable for testing a wireless telecommunication device. The testing adapter comprises a first contact member (102A) and a second contact member (102B), the first contact member (102A) and the second contact member (102B) having at least one degree of freedom relative to each other and arranged to provide an attachable and detachable mechanical coupling with a surface of a component recess of the wireless telecommunication device on the basis of the at least one degree of freedom.

Full Text	Testing adapter Field The invention relates to a testing adapter for testing a wireless tele- communication device. Background The manufacture of wireless telecommunication devices involves a complex testing procedure where a wireless telecommunication device is placed into a testing arrangement and subjected to mechanical and electronic tests. The testing procedure involves a mechanical contact between the testing arrangement and the wireless telecommunication device in order to position and handle the wireless telecommunication device. The formation of the me- chanical contact effects the time used for the testing procedure and techniques required for accessing a testing interface of the wireless telecommunication device. Therefore, it is useful to consider techniques for testing a wireless tele- communication device. Brief description of the invention An object of the invention is to provide an improved testing adapter. According to an aspect of the invention, there is provided a testing adapter for testing a wireless telecommunication device, the testing adapter comprising a first contact member and a second contact member, the first contact member and the second contact member having at least one degree of freedom relative to each other and arranged to provide an attachable and detachable mechani- cal coupling with a surface of a component recess of the wireless telecommu- nication device on the basis of the at least one degree of freedom. The invention provides several advantages. The use of the compo- nent recess as a mechanical contact surface between the testing adapter and the wireless telecommunication device provides an efficient way to handle a wireless telecommunication device in a test environment. Furthermore, the use of the component recess as the mechanical contact surface reduces the expo- sure of the cover of the wireless telecommunication device to mechanical stress and visual defects. List of drawhngs In the following, the invention will be described in greater detail with reference to the embodiments and the accompanying drawings, in which Figure 1A shows a first example of a structure of a testing adapter according to a first embodiment; Figure 1B shows a second example of a structure of a testing adapter according to a first embodiment; Figure 2 shows a third example of a structure of a testing adapter according to a first embodiment; Figure 3 shows a first example of a structure of a testing adapter according to a second embodiment; Figure 4 shows a second example of a structure of a testing adapter according to a second embodiment; Figure 5 shows a third example of a structure of a testing adapter according to a second embodiment; Figure 6 shows a first example of a structure of a testing adapter according to a third embodiment; Figure 7 shows a second example of a structure of a testing adapter according to a third embodiment; Figure 8 shows a third example of a structure of a testing adapter according to a third embodiment; Figure 9 shows a fourth example of a structure of a testing adapter according to a third embodiment; Figure 10 shows a first example of a structure of a testing adapter according to a fourth embodiment; Figure 11 shows a second example of a structure of a testing adapter according to a fourth embodiment; Figure 12 shows a third example of a structure of a testing adapter according to a fourth embodiment, and Figure 13 shows an example of a structure of a testing adapter ac- cording to a fifth embodiment. Description of embodiments With reference to Figure 1, examine an example of the structure of a testing adapter 100 according to an embodiment of the invention. The testing adapter 100 comprises a first contact member 102A and a second contact member 102B. The first contact member 102A and the second contact mem- ber 102B are dimensioned and mutually located such that the testing adapter 100 may be fitted into a component recess 124 of a wireless telecommunica- tion device 110. The wireless telecommunication device 110 may also be referred to as a mobile phone, a cellular phone, user equipment, a mobile station, a mo- bile terminal and/or a wireless telecommunication modem. The present solu- tion, is not, however, restricted to the listed devices, but may be applied to any wireless telecommunication device connectable to a wireless telecommunica- tion network. The first contact member 102A and the second contact member 102B have at least one degree of freedom 104 relative to each other so that the relative position of the first contact member 102A and the second contact member 102B may be changed, thus providing an attachable and detachable mechanical coupling between the testing adapter 100 and a surface 120A - 120D of the component recess 124. The degree of freedom 104 may be a rotational degree of freedom, which enables relative rotation between the first contact member 102A and the second contact member 102B. The relative rotation may be pivoted such that the overall dimensions of the testing adapter 100 are changed during the rela- tive rotation, thus enabling the testing adapter 100 to be attached to and be detached from the component recess 124. The at least one degree of freedom 104 has a component parallel to a line between opposite portions of the surface 120A to 120D of the compo- nent recess 124. Opposite portions are, for example, portion 120C and portion 120D. The relative position of the first contact member 102A and the sec- ond contact member 102B may be controlled by an actuator mechanism 112, which may be integrated into the first contact member 102A and/or the second contact member 102B. The testing adapter 100 is pressed in an installation direction 106 into the component recess 124 in a disengaged position of the testing adapter 100. In the disengaged position, the separation between the first contact member 102A and the second contact member 102B is less than the separa- tion between the opposite portions 120C, 120D of the component recess 124. Then, the separation between the first contact member 102A and the second contact member 102A is increased. When the separation is sufficient to pro- vide the mechanical coupling, an engaged position is attained, and the wire- less telecommunication device 110 is mechanically supported by the testing adapter 100. The engaged position enables the wireless telecommunication device 110 to be subjected to a testing procedure. The testing procedure may involve an access to, for example, a user interface, data buses and/or power connections of the wireless telecommunication device 110. The testing proce- dure may also involve a visual inspection of the wireless telecommunication device 110 by a testing system and/or testing personnel. The testing adapter 100 may be mounted to the testing system not shown in Figure 1A. The testing system may include a stand for positioning the testing adapter 100 into a position suitable for the testing system and/or testing personnel. The component recess 124 is typically a hollow for an attachable and a detachable component, such as a battery or a memory card. The com- ponent recess 124 may also be referred to as a battery grave or a card slot depending on the embodiment. The testing adapter 100 may be fitted accord- ing to the shape of the surface 120A to 120D of the component recess 124 in order to ensure a sufficient mechanical coupling. The first contact member 102A and the second contact member 102B are made of solid material, such as plastic, ceramics or metal. With further reference to Figure 1A, the testing adapter 100 may comprise at least one electric contact member 114 for providing an electric coupling with an electric contact 108, 116 located in the component recess 124. The electric contact member 114 is connected to an electric connector 122, which electric connector 122 is further connected to the testing system. The electric contact members 114 provide an electric access from the testing system to electric test objects, such as power supply, SIM card slot (Subscribe Identity Module), motherboard contact points or test pads, of the wireless tele- communication device 110. The electric access enables test signals to be in- putted into and response signals to be outputted from the wireless telecommu- nication device 110. The electric contact members 114 may be located in ac- cordance with the location of the electric contacts 108, 116. With reference to Figure 1B, the testing adapter 100 is shown from a component-recess side. Electric contact members 118 contacting electric contacts 116 located in the bottom of the component recess 124 are shown. The electric contact members 114, 118 may slightly extend from the first con- tact member 102A and the second contact member 102B in order to ensure a sufficient electric coupling with the electric contacts 108, 116. The electric con- tacts 114,118 may be equipped with a suspension mechanism, which limits mechanical force between the electric contact member 114, 118 and the elec- tric contact 108, 116 when the testing adapter 100 is in the engaged position. Figure 2 shows an example of the testing adapter 100 connected to an external support 126, such as a stand. In this example, the testing adapter 100 is in the engaged position, and the electric contact members 114, 118 are connected to the electric contacts 108, 116. With reference to examples shown in Figures 3 to 12, in an em- bodiment of the invention, the testing adapter 100 comprises a force transform- ing mechanism coupled with the first contact member 102A and the second contact member 102B. The force transforming mechanism transforms a first force component 304 into a second force component 302, wherein the first force component 304 is generated when the testing adapter 100 is pressed into the component recess 124. The second force component 302 is parallel to a line between opposite portions 120C, 120D of the surface of the component recess 124, thus providing a mechanical coupling between the portion 120D and the first contact member 102A and a mechanical coupling between the portion 120C of the component recess 124 and the second contact member 102B. The testing adapter 100 may be pressed into the component recess 124 by testing personnel or by an automated mechanism, such as a robot arm. With reference to Figure 3, the force transform mechanism may be implemented by setting the first contact member 102A and the second contact member 102B against each other and by introducing a folding contact 306 be- tween the first contact member 102A and the second contact member 102B. In the disengaged position of the testing adapter 100, a point of the testing adapter in the vicinity of the folding contact 306 is separated from the bottom of the component recess 124, and the end of the first contact member 102A and the end of the second contact member 102B locate in the vicinity of the bottom of the component recess 124. In this case, the first contact member 102A and the second contact member 102B form a flexible V-shaped testing adapter 100, whose ends approach the opposite portions 120C, 120D of the surface of the component recess 124 when the first force component 304 is applied to the testing adapter 100. In an embodiment of the invention, the mechanical transmission mechanism comprises a first gear 300A connected to the first contact member 102A and a second gear 300B connected to the second contact member 102B. The first gear 300A and the second gear 300B are compatible with each other, for example, in terms of a tooth size and a tooth separation. The first gear 300A and the second gear 300B are coupled to each other and arranged to transmit rotational force between each other. The gears 300A, 300B may replace a need for the folding contact 306, thus providing a rigid contact be- tween the first contact member 102A and the second contact member 102B in a large scale of rotational angles between the first contact member 102A and the second contact member 102B. With reference to an example shown Figure 4, the testing adapter 100 of Figure 3 is shown in the engaged position. The first contact member 102A is in contact with the surface portion 120D while the second contact member is in contact with the surface portion 120C, thus coupling the testing adapter 100 mechanically with the wireless telecommunication device 110. The electric contact member 114 is in contact with the electric contact 108 of the component recess 124. Figure 4 also shows a portion of an extension 400 of the electric contact member 114, which extension 400 may be connected to a wire or other means for electrically connecting the electric contact member 114 to the testing system. With reference to an example shown in Figure 5, a testing adapter configuration of Figures 3 and 4 is shown from another perspective. Figure 5 shows the extension 400 and further electric contact members 500 for con- necting to electric contacts 118 located in the bottom of the component recess 124. Also, positioning means 504 for providing an accurate mechanical posi- tion of the testing adapter 100 relative to the wireless telecommunication de- vice 110 are shown. With reference to an example shown in Figures 6 to 9, in an em- bodiment of the invention, the first contact member 102A comprises first guid- ing means 600 for guiding the second contact member 102B apart from the first contact member 102A when the testing adapter is pressed into the com- ponent recess 124, thus forming the mechanical coupling between the testing adapter 100 and the surface 120C, 120D of the component recess 124. The first guiding means 600 may be a groove 600 formed in the side of the first contact member 102A. The second contact member 102B may comprise an extension 602, such as a bar, which extends from the body of the second contact member 102B into the groove 600. The guiding means 600 may also be a protruded guiding structure, such as a guiding rail, extending from the first contact member 102A. In such a case, the second contact member 102B comprises a contact structure com- patible with the protruded guiding structure. The guiding means 600 may have curvature so that the second con- tact member 102B has a curved trajectory when moving the second contact member 102B along the guiding means 600. When applying the first force component 304 to the first contact member 102A, the second contact member 102B follows the curved trajectory relative to the first contact member 102A, thus generating a second force component 302, which increases the relative position of the first contact member 102A and the second contact member 102B. In Figure 6, the testing adapter 100 is in the disengaged position while in Figure 7, the testing adapter 100 is reaching the engaged position. In Figure 8, the testing adapter of Figures 6 and 7 is in the engaged position. Figure 8 shows the electric contact member 114 which is electrically coupled with the electric contact 108. The extension 400 of the electric contact member 114 and an electric contact member 800 connected to the electric contacts 118 of the bottom of the component recess 124 are also shown. Figure 9 shows the testing adapter of Figures 6 to 8 from another perspective. A plurality of extensions 400 of the electric contact members 108 are shown. The testing adapter 100 may further comprise a plurality of electric contact members 800 connecting to the electric contacts 118 located in the bottom of the component recess 124. With reference to examples of Figures 10 to 12, in an embodiment of the invention, the testing adapter 100 comprises a body 920 coupled with the first contact member 102A and the second contact member 102B. The body 920 comprises a second guiding means 926, 928, which guides the sec- ond contact member 102B apart from the first contact member 102A when the testing adapter 100 is pressed into the component recess 124, thus forming the mechanical coupling between the testing adapter 100 and the surface 120C, 120D of the component recess 124. In an embodiment of the invention, the body 920 comprises the second guiding means 926 for guiding the first contact member 102A, and the second contact member 102B is connected to the body 920. In such a case, the second guiding means 928 for guiding the second contact member 102B may not exist. The second guiding means 926, 928 may be a groove formed in the body 920. The second guiding means 926, 928 may also be a protruded guid- ing structure. The first contact member 102A and the second contact member 102B may have an extension 922 and 924, respectively, to be guided by the second guiding means 926, 928. The guiding means 926, 928 may have curvature so that the first contact member 102A and the second contact member 102B have curved tra- jectories when moving the first contact member 102A and the second contact member 102B along the guiding means 926, 928. When applying the first force component 304 to the body 920, the first contact member 102A and the sec- ond contact member 102B follow the curved trajectories, thus generating a second force component 302, which increases the relative position of the first contact member 102A and the second contact member 102B. In Figure 10, the testing adapter 100 is in the disengaged position while in Figures 11 and 12, the testing adapter 100 is in the engaged positions. Figure 11 further shows the extension 400 and the electric contact member 114 connected to the electric contact 108. The electric contact mem- bers 800 contacting the electric contacts 118 located in the bottom of the com- ponent recess 124 are shown. With reference to Figure 12, another perspective of Figures 10 and 11 is shown. Figure 12 shows the gears 940A, 940B, whose function and structure may be similar to those described in conjunction with Figures 3 to 5. With reference to Figure 13, in an embodiment of the invention, the first contact member 102A comprises a third guiding means 944, such as guid- ing rails, for guiding the second contact member 102B in the direction compris- ing a direction component parallel to a line between the opposite portions 120C, 120D of the surface of the component recess 124. The testing adapter 100 further comprises a force transmission means 942 coupled with the first contact member 102A or the second contact member 102B. The force trans- mission means 942 transmits an external force 948 for sliding the first contact member 102A relative to the second contact member 102B. The force trans- mission means 942 may comprise a bar extending from the first contact mem- ber 102A or the second contact member 102B, and a bearing 952 for providing a smooth support from an external structure 950. The second contact member 102B may comprise an open groove compatible with the guiding means 944 in order to provide a sufficient me- chanical contact between the first contact member 102A and the second con- tact member 102B. The testing adapter 100 may further be axially pivoted to the exter- nal structure 950. The force transmission means 942 is supported by the ex- ternal structure 950 when the testing adapter 100 is rotated about an axial pivot 940, thus causing the first contact member 102A to slide along the third guiding means 944. In the example of Figure 13, the testing adapter 100 is arranged to provide the engaged position when the force directed at the force transmission means 942 from the external support 950 is decreased. The force from the external support 950 may be controlled by turning the wireless tele- communication device 110 in the direction shown by arrow 946. The testing adapter 100 may further comprise a force means, such as a spring, for forcing the testing adapter 100 into the engaged position when the external support 950 is not applied. The testing adapter 100 is released from the engaged posi- tion when supporting the testing adapter 100 to the external support 950. Even though the invention has been described above with reference to an example according to the accompanying drawings, it is clear that the in- vention is not restricted thereto but it can be modified in several ways within the scope of the appended claims. Claims 1. A testing adapter for testing a wireless telecommunication device, characterized in that the testing adapter comprises a first contact mem- ber (102A) and a second contact member (102B), the first contact member (102A) and the second contact member (102B) having at least one degree of freedom relative to each other and arranged to provide an attachable and de- tachable mechanical coupling with a surface of a component recess of the wireless telecommunication device on the basis of the at least one degree of freedom. 2. The testing adapter of claim 1, characterized in that the testing adapter further comprises at least one electric contact member (114, 118) for providing an electric coupling with an electric contact located in the component recess. 3. The testing adapter of claim 1, characterized in that the second contact member (102A) and the first contact member (102B) are ar- ranged to provide the mechanical coupling with a component recess selected from a group comprising: a battery grave, a card slot. 4. The testing adapter of claim 1, characterized in that the testing adapter comprises a force transforming mechanism coupled with the first contact member (102A) and the second contact member (102B), for trans- forming a first force component (304) into a second force component (302), wherein the first force component (304) is generated when the testing adapter is pressed into the component recess, the second force component (302) be- ing parallel to a line between opposite portions of the surface of the component recess, thus providing a mechanical coupling between the surface of the com- ponent recess and the first contact member (102A) and a mechanical coupling between the surface of the component recess and the second contact member (102B). 5. The testing adapter of claim 4, characterized in that the mechanical transmission mechanism comprises a first gear (300A) connected to the first contact member (102A) and a second gear (300B) connected to the second contact member (102B), the first gear (300A) and the second gear (300B) being arranged to transmit a rotational force between each other. 6. The testing adapter of claim 4, characterized in that the first contact member (102A) comprises first guiding means (600) for guiding the second contact member (102B) apart from the first contact member (102A) when the testing adapter is pressed into the component recess, thus forming the mechanical coupling between the testing adapter and the surface of the component recess. 7. The testing adapter of claim 4, characterized in that the testing adapter comprises a body (920) coupled with the first contact member (102A) and the second contact member (102B), the body (920) comprising a second guiding means (926, 928) for guiding the second contact member (102B) apart from the first contact member (102A) when the testing adapter is pressed into the component recess, thus forming the mechanical coupling be- tween the testing adapter and the surface of the component recess. 8. The testing adapter of claim 1, characterized in that the first contact member (102A) comprises a third guiding means (944) for guiding the second contact member (102B) in the direction comprising a direction component parallel to a line between opposite portions of the surface of the component recess, the testing adapter further comprising a force transmission means (942) coupled with the first contact member (102A) or the second con- tact member (102B), for transmitting an external force for sliding the first con- tact member (102A) relative to the second contact member (102B), the testing adapter further being axially pivoted to an external structure, the force trans- mission means (942) being arranged to be supported by the external structure when the testing adapter is rotated about an axial pivot, thus causing the first contact member (102A) to slide along the third guiding means (944). The invention relates to a testing adapter suitable for testing a wireless telecommunication device. The testing adapter comprises a first contact member (102A) and a second contact member (102B), the first contact member (102A) and the second contact member (102B) having at least one degree of freedom relative to each other and arranged to provide an attachable and detachable mechanical coupling with a surface of a component recess of the wireless telecommunication device on the basis of the at least one degree of freedom.

Full Text

Testing adapter
Field
The invention relates to a testing adapter for testing a wireless tele-
communication device.
Background
The manufacture of wireless telecommunication devices involves a
complex testing procedure where a wireless telecommunication device is
placed into a testing arrangement and subjected to mechanical and electronic
tests. The testing procedure involves a mechanical contact between the testing
arrangement and the wireless telecommunication device in order to position
and handle the wireless telecommunication device. The formation of the me-
chanical contact effects the time used for the testing procedure and techniques
required for accessing a testing interface of the wireless telecommunication
device. Therefore, it is useful to consider techniques for testing a wireless tele-
communication device.
Brief description of the invention
An object of the invention is to provide an improved testing adapter.
According to an aspect of the invention, there is provided a testing adapter for
testing a wireless telecommunication device, the testing adapter comprising a
first contact member and a second contact member, the first contact member
and the second contact member having at least one degree of freedom relative
to each other and arranged to provide an attachable and detachable mechani-
cal coupling with a surface of a component recess of the wireless telecommu-
nication device on the basis of the at least one degree of freedom.
The invention provides several advantages. The use of the compo-
nent recess as a mechanical contact surface between the testing adapter and
the wireless telecommunication device provides an efficient way to handle a
wireless telecommunication device in a test environment. Furthermore, the use
of the component recess as the mechanical contact surface reduces the expo-
sure of the cover of the wireless telecommunication device to mechanical
stress and visual defects.

List of drawhngs
In the following, the invention will be described in greater detail with
reference to the embodiments and the accompanying drawings, in which
Figure 1A shows a first example of a structure of a testing adapter
according to a first embodiment;
Figure 1B shows a second example of a structure of a testing
adapter according to a first embodiment;
Figure 2 shows a third example of a structure of a testing adapter
according to a first embodiment;
Figure 3 shows a first example of a structure of a testing adapter
according to a second embodiment;
Figure 4 shows a second example of a structure of a testing adapter
according to a second embodiment;
Figure 5 shows a third example of a structure of a testing adapter
according to a second embodiment;
Figure 6 shows a first example of a structure of a testing adapter
according to a third embodiment;
Figure 7 shows a second example of a structure of a testing adapter
according to a third embodiment;
Figure 8 shows a third example of a structure of a testing adapter
according to a third embodiment;
Figure 9 shows a fourth example of a structure of a testing adapter
according to a third embodiment;
Figure 10 shows a first example of a structure of a testing adapter
according to a fourth embodiment;
Figure 11 shows a second example of a structure of a testing
adapter according to a fourth embodiment;
Figure 12 shows a third example of a structure of a testing adapter
according to a fourth embodiment, and
Figure 13 shows an example of a structure of a testing adapter ac-
cording to a fifth embodiment.
Description of embodiments
With reference to Figure 1, examine an example of the structure of a
testing adapter 100 according to an embodiment of the invention. The testing
adapter 100 comprises a first contact member 102A and a second contact

member 102B. The first contact member 102A and the second contact mem-
ber 102B are dimensioned and mutually located such that the testing adapter
100 may be fitted into a component recess 124 of a wireless telecommunica-
tion device 110.
The wireless telecommunication device 110 may also be referred to
as a mobile phone, a cellular phone, user equipment, a mobile station, a mo-
bile terminal and/or a wireless telecommunication modem. The present solu-
tion, is not, however, restricted to the listed devices, but may be applied to any
wireless telecommunication device connectable to a wireless telecommunica-
tion network.
The first contact member 102A and the second contact member
102B have at least one degree of freedom 104 relative to each other so that
the relative position of the first contact member 102A and the second contact
member 102B may be changed, thus providing an attachable and detachable
mechanical coupling between the testing adapter 100 and a surface 120A -
120D of the component recess 124.
The degree of freedom 104 may be a rotational degree of freedom,
which enables relative rotation between the first contact member 102A and the
second contact member 102B. The relative rotation may be pivoted such that
the overall dimensions of the testing adapter 100 are changed during the rela-
tive rotation, thus enabling the testing adapter 100 to be attached to and be
detached from the component recess 124.
The at least one degree of freedom 104 has a component parallel to
a line between opposite portions of the surface 120A to 120D of the compo-
nent recess 124. Opposite portions are, for example, portion 120C and portion
120D.
The relative position of the first contact member 102A and the sec-
ond contact member 102B may be controlled by an actuator mechanism 112,
which may be integrated into the first contact member 102A and/or the second
contact member 102B.
The testing adapter 100 is pressed in an installation direction 106
into the component recess 124 in a disengaged position of the testing adapter
100. In the disengaged position, the separation between the first contact
member 102A and the second contact member 102B is less than the separa-
tion between the opposite portions 120C, 120D of the component recess 124.
Then, the separation between the first contact member 102A and the second

contact member 102A is increased. When the separation is sufficient to pro-
vide the mechanical coupling, an engaged position is attained, and the wire-
less telecommunication device 110 is mechanically supported by the testing
adapter 100. The engaged position enables the wireless telecommunication
device 110 to be subjected to a testing procedure. The testing procedure may
involve an access to, for example, a user interface, data buses and/or power
connections of the wireless telecommunication device 110. The testing proce-
dure may also involve a visual inspection of the wireless telecommunication
device 110 by a testing system and/or testing personnel.
The testing adapter 100 may be mounted to the testing system not
shown in Figure 1A. The testing system may include a stand for positioning the
testing adapter 100 into a position suitable for the testing system and/or testing
personnel.
The component recess 124 is typically a hollow for an attachable
and a detachable component, such as a battery or a memory card. The com-
ponent recess 124 may also be referred to as a battery grave or a card slot
depending on the embodiment. The testing adapter 100 may be fitted accord-
ing to the shape of the surface 120A to 120D of the component recess 124 in
order to ensure a sufficient mechanical coupling.
The first contact member 102A and the second contact member
102B are made of solid material, such as plastic, ceramics or metal.
With further reference to Figure 1A, the testing adapter 100 may
comprise at least one electric contact member 114 for providing an electric
coupling with an electric contact 108, 116 located in the component recess
124. The electric contact member 114 is connected to an electric connector
122, which electric connector 122 is further connected to the testing system.
The electric contact members 114 provide an electric access from the testing
system to electric test objects, such as power supply, SIM card slot (Subscribe
Identity Module), motherboard contact points or test pads, of the wireless tele-
communication device 110. The electric access enables test signals to be in-
putted into and response signals to be outputted from the wireless telecommu-
nication device 110. The electric contact members 114 may be located in ac-
cordance with the location of the electric contacts 108, 116.
With reference to Figure 1B, the testing adapter 100 is shown from
a component-recess side. Electric contact members 118 contacting electric
contacts 116 located in the bottom of the component recess 124 are shown.

The electric contact members 114, 118 may slightly extend from the first con-
tact member 102A and the second contact member 102B in order to ensure a
sufficient electric coupling with the electric contacts 108, 116. The electric con-
tacts 114,118 may be equipped with a suspension mechanism, which limits
mechanical force between the electric contact member 114, 118 and the elec-
tric contact 108, 116 when the testing adapter 100 is in the engaged position.
Figure 2 shows an example of the testing adapter 100 connected to
an external support 126, such as a stand. In this example, the testing adapter
100 is in the engaged position, and the electric contact members 114, 118 are
connected to the electric contacts 108, 116.
With reference to examples shown in Figures 3 to 12, in an em-
bodiment of the invention, the testing adapter 100 comprises a force transform-
ing mechanism coupled with the first contact member 102A and the second
contact member 102B. The force transforming mechanism transforms a first
force component 304 into a second force component 302, wherein the first
force component 304 is generated when the testing adapter 100 is pressed
into the component recess 124. The second force component 302 is parallel to
a line between opposite portions 120C, 120D of the surface of the component
recess 124, thus providing a mechanical coupling between the portion 120D
and the first contact member 102A and a mechanical coupling between the
portion 120C of the component recess 124 and the second contact member
102B.
The testing adapter 100 may be pressed into the component recess
124 by testing personnel or by an automated mechanism, such as a robot arm.
With reference to Figure 3, the force transform mechanism may be
implemented by setting the first contact member 102A and the second contact
member 102B against each other and by introducing a folding contact 306 be-
tween the first contact member 102A and the second contact member 102B. In
the disengaged position of the testing adapter 100, a point of the testing
adapter in the vicinity of the folding contact 306 is separated from the bottom of
the component recess 124, and the end of the first contact member 102A and
the end of the second contact member 102B locate in the vicinity of the bottom
of the component recess 124. In this case, the first contact member 102A and
the second contact member 102B form a flexible V-shaped testing adapter
100, whose ends approach the opposite portions 120C, 120D of the surface of

the component recess 124 when the first force component 304 is applied to the
testing adapter 100.
In an embodiment of the invention, the mechanical transmission
mechanism comprises a first gear 300A connected to the first contact member
102A and a second gear 300B connected to the second contact member
102B. The first gear 300A and the second gear 300B are compatible with each
other, for example, in terms of a tooth size and a tooth separation. The first
gear 300A and the second gear 300B are coupled to each other and arranged
to transmit rotational force between each other. The gears 300A, 300B may
replace a need for the folding contact 306, thus providing a rigid contact be-
tween the first contact member 102A and the second contact member 102B in
a large scale of rotational angles between the first contact member 102A and
the second contact member 102B.
With reference to an example shown Figure 4, the testing adapter
100 of Figure 3 is shown in the engaged position. The first contact member
102A is in contact with the surface portion 120D while the second contact
member is in contact with the surface portion 120C, thus coupling the testing
adapter 100 mechanically with the wireless telecommunication device 110.
The electric contact member 114 is in contact with the electric contact 108 of
the component recess 124. Figure 4 also shows a portion of an extension 400
of the electric contact member 114, which extension 400 may be connected to
a wire or other means for electrically connecting the electric contact member
114 to the testing system.
With reference to an example shown in Figure 5, a testing adapter
configuration of Figures 3 and 4 is shown from another perspective. Figure 5
shows the extension 400 and further electric contact members 500 for con-
necting to electric contacts 118 located in the bottom of the component recess
124. Also, positioning means 504 for providing an accurate mechanical posi-
tion of the testing adapter 100 relative to the wireless telecommunication de-
vice 110 are shown.
With reference to an example shown in Figures 6 to 9, in an em-
bodiment of the invention, the first contact member 102A comprises first guid-
ing means 600 for guiding the second contact member 102B apart from the
first contact member 102A when the testing adapter is pressed into the com-
ponent recess 124, thus forming the mechanical coupling between the testing
adapter 100 and the surface 120C, 120D of the component recess 124.

The first guiding means 600 may be a groove 600 formed in the side
of the first contact member 102A. The second contact member 102B may
comprise an extension 602, such as a bar, which extends from the body of the
second contact member 102B into the groove 600.
The guiding means 600 may also be a protruded guiding structure,
such as a guiding rail, extending from the first contact member 102A. In such a
case, the second contact member 102B comprises a contact structure com-
patible with the protruded guiding structure.
The guiding means 600 may have curvature so that the second con-
tact member 102B has a curved trajectory when moving the second contact
member 102B along the guiding means 600. When applying the first force
component 304 to the first contact member 102A, the second contact member
102B follows the curved trajectory relative to the first contact member 102A,
thus generating a second force component 302, which increases the relative
position of the first contact member 102A and the second contact member
102B. In Figure 6, the testing adapter 100 is in the disengaged position while
in Figure 7, the testing adapter 100 is reaching the engaged position.
In Figure 8, the testing adapter of Figures 6 and 7 is in the engaged
position. Figure 8 shows the electric contact member 114 which is electrically
coupled with the electric contact 108. The extension 400 of the electric contact
member 114 and an electric contact member 800 connected to the electric
contacts 118 of the bottom of the component recess 124 are also shown.
Figure 9 shows the testing adapter of Figures 6 to 8 from another
perspective. A plurality of extensions 400 of the electric contact members 108
are shown. The testing adapter 100 may further comprise a plurality of electric
contact members 800 connecting to the electric contacts 118 located in the
bottom of the component recess 124.
With reference to examples of Figures 10 to 12, in an embodiment
of the invention, the testing adapter 100 comprises a body 920 coupled with
the first contact member 102A and the second contact member 102B. The
body 920 comprises a second guiding means 926, 928, which guides the sec-
ond contact member 102B apart from the first contact member 102A when the
testing adapter 100 is pressed into the component recess 124, thus forming
the mechanical coupling between the testing adapter 100 and the surface
120C, 120D of the component recess 124.

In an embodiment of the invention, the body 920 comprises the
second guiding means 926 for guiding the first contact member 102A, and the
second contact member 102B is connected to the body 920. In such a case,
the second guiding means 928 for guiding the second contact member 102B
may not exist.
The second guiding means 926, 928 may be a groove formed in the
body 920. The second guiding means 926, 928 may also be a protruded guid-
ing structure.
The first contact member 102A and the second contact member
102B may have an extension 922 and 924, respectively, to be guided by the
second guiding means 926, 928.
The guiding means 926, 928 may have curvature so that the first
contact member 102A and the second contact member 102B have curved tra-
jectories when moving the first contact member 102A and the second contact
member 102B along the guiding means 926, 928. When applying the first force
component 304 to the body 920, the first contact member 102A and the sec-
ond contact member 102B follow the curved trajectories, thus generating a
second force component 302, which increases the relative position of the first
contact member 102A and the second contact member 102B. In Figure 10, the
testing adapter 100 is in the disengaged position while in Figures 11 and 12,
the testing adapter 100 is in the engaged positions.
Figure 11 further shows the extension 400 and the electric contact
member 114 connected to the electric contact 108. The electric contact mem-
bers 800 contacting the electric contacts 118 located in the bottom of the com-
ponent recess 124 are shown.
With reference to Figure 12, another perspective of Figures 10 and
11 is shown. Figure 12 shows the gears 940A, 940B, whose function and
structure may be similar to those described in conjunction with Figures 3 to 5.
With reference to Figure 13, in an embodiment of the invention, the
first contact member 102A comprises a third guiding means 944, such as guid-
ing rails, for guiding the second contact member 102B in the direction compris-
ing a direction component parallel to a line between the opposite portions
120C, 120D of the surface of the component recess 124. The testing adapter
100 further comprises a force transmission means 942 coupled with the first
contact member 102A or the second contact member 102B. The force trans-
mission means 942 transmits an external force 948 for sliding the first contact

member 102A relative to the second contact member 102B. The force trans-
mission means 942 may comprise a bar extending from the first contact mem-
ber 102A or the second contact member 102B, and a bearing 952 for providing
a smooth support from an external structure 950.
The second contact member 102B may comprise an open groove
compatible with the guiding means 944 in order to provide a sufficient me-
chanical contact between the first contact member 102A and the second con-
tact member 102B.
The testing adapter 100 may further be axially pivoted to the exter-
nal structure 950. The force transmission means 942 is supported by the ex-
ternal structure 950 when the testing adapter 100 is rotated about an axial
pivot 940, thus causing the first contact member 102A to slide along the third
guiding means 944. In the example of Figure 13, the testing adapter 100 is
arranged to provide the engaged position when the force directed at the force
transmission means 942 from the external support 950 is decreased. The force
from the external support 950 may be controlled by turning the wireless tele-
communication device 110 in the direction shown by arrow 946. The testing
adapter 100 may further comprise a force means, such as a spring, for forcing
the testing adapter 100 into the engaged position when the external support
950 is not applied. The testing adapter 100 is released from the engaged posi-
tion when supporting the testing adapter 100 to the external support 950.
Even though the invention has been described above with reference
to an example according to the accompanying drawings, it is clear that the in-
vention is not restricted thereto but it can be modified in several ways within
the scope of the appended claims.

Claims
1. A testing adapter for testing a wireless telecommunication device,
characterized in that the testing adapter comprises a first contact mem-
ber (102A) and a second contact member (102B), the first contact member
(102A) and the second contact member (102B) having at least one degree of
freedom relative to each other and arranged to provide an attachable and de-
tachable mechanical coupling with a surface of a component recess of the
wireless telecommunication device on the basis of the at least one degree of
freedom.
2. The testing adapter of claim 1, characterized in that the
testing adapter further comprises at least one electric contact member (114,
118) for providing an electric coupling with an electric contact located in the
component recess.
3. The testing adapter of claim 1, characterized in that the
second contact member (102A) and the first contact member (102B) are ar-
ranged to provide the mechanical coupling with a component recess selected
from a group comprising: a battery grave, a card slot.
4. The testing adapter of claim 1, characterized in that the
testing adapter comprises a force transforming mechanism coupled with the
first contact member (102A) and the second contact member (102B), for trans-
forming a first force component (304) into a second force component (302),
wherein the first force component (304) is generated when the testing adapter
is pressed into the component recess, the second force component (302) be-
ing parallel to a line between opposite portions of the surface of the component
recess, thus providing a mechanical coupling between the surface of the com-
ponent recess and the first contact member (102A) and a mechanical coupling
between the surface of the component recess and the second contact member
(102B).
5. The testing adapter of claim 4, characterized in that the
mechanical transmission mechanism comprises a first gear (300A) connected
to the first contact member (102A) and a second gear (300B) connected to the
second contact member (102B), the first gear (300A) and the second gear
(300B) being arranged to transmit a rotational force between each other.
6. The testing adapter of claim 4, characterized in that the
first contact member (102A) comprises first guiding means (600) for guiding
the second contact member (102B) apart from the first contact member (102A)

when the testing adapter is pressed into the component recess, thus forming
the mechanical coupling between the testing adapter and the surface of the
component recess.
7. The testing adapter of claim 4, characterized in that the
testing adapter comprises a body (920) coupled with the first contact member
(102A) and the second contact member (102B), the body (920) comprising a
second guiding means (926, 928) for guiding the second contact member
(102B) apart from the first contact member (102A) when the testing adapter is
pressed into the component recess, thus forming the mechanical coupling be-
tween the testing adapter and the surface of the component recess.
8. The testing adapter of claim 1, characterized in that the
first contact member (102A) comprises a third guiding means (944) for guiding
the second contact member (102B) in the direction comprising a direction
component parallel to a line between opposite portions of the surface of the
component recess, the testing adapter further comprising a force transmission
means (942) coupled with the first contact member (102A) or the second con-
tact member (102B), for transmitting an external force for sliding the first con-
tact member (102A) relative to the second contact member (102B), the testing
adapter further being axially pivoted to an external structure, the force trans-
mission means (942) being arranged to be supported by the external structure
when the testing adapter is rotated about an axial pivot, thus causing the first
contact member (102A) to slide along the third guiding means (944).

The invention relates to a testing adapter suitable for testing a wireless telecommunication device. The testing adapter comprises a first contact member (102A) and a second contact member (102B), the first contact member (102A) and the second contact member (102B) having at least one degree of freedom relative to each other and arranged to provide an attachable and detachable mechanical coupling with a surface of a component recess of the wireless telecommunication device on the basis of the at least one degree of freedom.

Documents:

http://ipindiaonline.gov.in/patentsearch/GrantedSearch/viewdoc.aspx?id=bP27/DpjEH9kxB++FdWunQ==&loc=wDBSZCsAt7zoiVrqcFJsRw==

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Patent Number

271383

Indian Patent Application Number

2396/KOLNP/2008

PG Journal Number

08/2016

Publication Date

19-Feb-2016

Grant Date

18-Feb-2016

Date of Filing

13-Jun-2008

Name of Patentee

JOT AUTOMATION OY

Applicant Address

PAULAHARJUNTIE 20 FI-90530 OULU

Inventors:

#	Inventor's Name	Inventor's Address
1	MAMMILA, TUOMO	ISKONTIE 14, FI-90550 OULU
2	KELLOKOSKI, MIKA	KOIVUPIHA 8, FI-90830 HAUKIPUDAS
3	PIIRAINEN, MIKA	ISOJAONTIE 19, FI-90650 OULU

PCT International Classification Number

G01R 1/04,G01R 1/073

PCT International Application Number

PCT/FI2005/050469

PCT International Filing date

2005-12-20

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1			NA