阅读说明：本技术 天线系统及其重启方法 (Antenna system and restarting method thereof ) 是由 廖子广 林文信 汤庆仲 谢宗勋 郑又福 于 2018-05-28 设计创作，主要内容包括：本发明提供一种天线系统及其重启方法,天线系统包含：多个天线、切换单元、通讯单元与控制单元。通讯单元经由各切换单元中为导通状态的各切换器接收对应的各天线的参考值组。控制单元自通讯单元接收各参考值组,并将参考值组与告警阀值进行比较,以判断各参考值组是否符合预期。当参考值组不符合预期时输出重启指令以重启切换单元。(The invention provides an antenna system and a restarting method thereof, wherein the antenna system comprises: the system comprises a plurality of antennas, a switching unit, a communication unit and a control unit. The communication unit receives the reference value group of each antenna through each switch which is in a conducting state in each switching unit. The control unit receives each reference value group from the communication unit and compares the reference value group with the alarm threshold value to judge whether each reference value group is in accordance with the expectation. And outputting a restart instruction to restart the switching unit when the reference value group does not meet the expectation.)

1. An antenna system, comprising:

A plurality of antennas;

A switching unit having a plurality of switches, each of the switches being in a conducting state or a breaking state with respect to the corresponding antenna;

A communication unit connected to each of the switches of the switching unit to be coupled to the antennas through the switches, the communication unit receiving a reference value set of the corresponding antenna from the switch in the on state; and

And the control unit is connected with the switching unit and the communication unit, receives the reference value group from the communication unit, compares the reference value group with an alarm threshold value to judge whether the reference value group is in accordance with the expectation, and outputs a restart instruction to restart the switching unit when the reference value group is not in accordance with the expectation.

2. the antenna system of claim 1, wherein when the switching unit is restarted, the switches are all switched to the on state, the control unit receives the feedback values of each of the antennas, generates a selection command according to at least one of the feedback values, and transmits the selection command to the switching unit, the switching unit selects the corresponding switch according to the selection command, maintains the on state of the switch, and switches the remaining switches to the off state.

3. The antenna system of claim 2, wherein when the switching unit is restarted, the control unit sequences the echo values to generate a sequence result, and selects at least one of the echo values that is ranked earlier according to the sequence result to generate the corresponding selection command.

4. The antenna system of claim 2, wherein an alarm threshold adjustment procedure is initiated when the switch unit is continuously restarted several times and the return values received by the control unit for each of the antennas are not compared with the alarm threshold as expected.

5. the antenna system of claim 1, wherein the control unit further comprises a positioning element, the positioning element communicating with a global positioning system to obtain current positioning information as the set of reference values, the control unit setting previous positioning information as the alarm threshold, comparing the current positioning information with the previous positioning information, and generating the restart command when the current positioning information is different from the previous positioning information.

6. The antenna system of claim 1, wherein the control unit further comprises a gravity sensing element, the gravity sensing element senses dynamic changes of the antenna system to generate current gravity sensing information as a system state reference value, the control unit sets previous gravity sensing information as the alarm threshold value, compares the current gravity sensing information with the previous gravity sensing information, and generates the restart command when the current gravity sensing information is different from the previous gravity sensing information.

7. The antenna system of claim 1, wherein the set of reference values includes a front reference value and a rear reference value, the alarm threshold is a degree of degradation corresponding to the set of reference values, the control unit obtains the front reference value at a first time, the control unit obtains the rear reference value at a second time, the control unit calculates a difference between the front reference value and the rear reference value, compares the difference with the alarm threshold to determine whether the difference is in accordance with an expected value, and generates the restart command when the difference is determined not to be in accordance with the expected value.

8. The antenna system of claim 1, wherein the reference values are associated with respective connection times of the antennas, the alarm threshold is a predetermined connection time, the control unit compares the connection times with the predetermined connection time to determine whether the connection times match, and generates the restart command when the connection times do not match the predetermined connection time.

9. The antenna system of claim 1, wherein the control unit has a plurality of restart time points, and the control unit outputs the restart command at the restart time points, wherein the time interval between the restart time points increases in an exponential time interval manner or a multiple time interval manner as the standby time of the antenna system becomes longer.

10. a method for restarting an antenna system, comprising:

Receiving a reference value group from the antenna corresponding to at least one switch which is in a conducting state in the switching unit;

Comparing the reference value group with an alarm threshold value to judge whether the reference value group is in accordance with expectation; and

and outputting a restart instruction to restart the switching unit when the reference value group does not meet the expectation.

11. the method of claim 10, wherein the step of restarting the switch unit further comprises:

Switching all the switches in the switching unit to the conducting state;

Receiving the feedback values of the antennas;

Generating a selection command according to at least one of the feedback values and transmitting the selection command to the switching unit; and

Selecting the corresponding switch according to the selection command and maintaining the switch in the on state, and switching the rest switches into the off state.

12. The method of claim 11, wherein the step of generating a selection command according to a preferred at least one of the return values and sending the selection command to the switch unit further comprises:

sorting the return values to generate a sorting result; and

selecting at least one of the return values with the earlier sequence according to the sequence result to generate the corresponding selection instruction.

13. The method of restarting an antenna system according to claim 11, further comprising: and starting an alarm threshold value adjusting program when the control unit judges that the feedback values of the antennas are not in accordance with the alarm threshold value every time when the switching unit is restarted for a plurality of times continuously.

14. the method of claim 10, wherein the set of reference values comprises a pre-reference value and a post-reference value, the method further comprising:

Obtaining the pre-reference value at a first time;

Obtaining the later reference value at a second time;

Calculating a difference between the rear reference value and the front reference value; and

Comparing the difference value with the alarm threshold value, and outputting the restart instruction to restart the switching unit when the difference value is not in accordance with expectation;

wherein the alarm threshold is a degree of amplitude reduction corresponding to the reference value.

15. the method of claim 10, wherein the set of reference values includes current positioning information and the alarm threshold is previous positioning information, the method further comprising:

Obtaining the current positioning information; and

Comparing the current positioning information with the previous positioning information;

When the current positioning information is different from the previous positioning information, the restart instruction is output to restart the switching unit.

16. the method of claim 10, wherein the set of reference values includes current gravity sensing information and the alarm threshold is previous gravity sensing information, the method further comprising:

Obtaining the current gravity sensing information; and

comparing the current gravity sensing information with the previous gravity sensing information;

And outputting the restart instruction to restart the switching unit when the current gravity sensing information is different from the previous gravity sensing information.

17. the method of claim 10, wherein the reference value set is a corresponding connection time of the antenna, the alarm threshold is a predetermined connection time, and the method further comprises:

Receiving the connection time of the antenna corresponding to the switch in the conducting state; and

Comparing the connection time with the preset connection time to judge whether the connection time is in accordance with the expectation;

When the connection time is not in accordance with the expectation, the restart instruction is output to restart the switching unit.

18. the method of claim 10, further comprising a plurality of restart time points, the method further comprising:

Outputting the restart instruction at the restart time points;

Wherein, when the standby time is longer, the restart time points are increased in an exponential time interval mode or a multiple time interval mode.

Technical Field

the present invention relates to an antenna system.

Background

As technology advances, many electronic devices of various types are equipped with wireless communication components. However, under different environmental influences, such as when a human body approaches an antenna, is far away from a base station or is deviated in direction, and is shielded by a room wall, the multi-antenna radiation pattern coverage is affected, which causes a poor communication capability or a dead angle in communication of the communication device at certain angles, and further affects the user experience.

Disclosure of Invention

In view of this, an embodiment of the present invention provides an antenna system including: the system comprises a plurality of antennas, a switching unit, a communication unit and a control unit. The switching unit is provided with a plurality of switches, and each switch and each corresponding antenna are in a conducting state or an open-circuit state. The communication unit is connected with each switcher of the switching unit so as to be coupled with each antenna through each switcher. The communication unit receives the reference value set of each antenna from the switches in the conducting state. The control unit is connected with the switching unit and the communication unit, receives the reference value groups from the communication unit, and compares the reference value groups with the alarm threshold value to judge whether any one of the reference value groups meets the expectation. And outputting a restart instruction to restart the switching unit when the reference value group does not meet the expectation.

the present invention further provides a method for restarting an antenna system, comprising: receiving a reference value group from an antenna corresponding to at least one switch which is in a conducting state in a switching unit; comparing the reference value group with an alarm threshold value to judge whether the reference value group meets the expectation; and outputting a restart instruction to restart the switching unit when the reference value set does not meet the expectation.

According to the above, after comparing the feedback value of each antenna with the alarm threshold, the present invention can further restart the antenna system to further drive the switch in the switching unit to change to the off state or the on state again. Therefore, a proper antenna can be found to maintain a proper radiation field pattern, so that good wireless transmission quality can be kept at any time, and a user can further keep the use feeling.

other features and embodiments of the present invention will be described in detail below with reference to the drawings.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments described in the present application, and other drawings can be obtained by those skilled in the art without creative efforts.

fig. 1 is a schematic configuration diagram of an antenna system according to an embodiment of the present invention.

fig. 2A is a diagram of a restart method of the antenna system according to the present invention.

Fig. 2B is a diagram of a restart procedure of the antenna system restart method of the present invention.

fig. 3 is a schematic diagram of a restart procedure of the antenna system of the present invention.

Fig. 4 is a diagram illustrating an antenna system according to an embodiment of the present invention after being restarted.

Fig. 5 is a schematic time interval diagram of a restart time point of the antenna system of the present invention.

fig. 6 is a schematic step diagram of a first embodiment of the antenna system of the present invention.

Detailed Description

Referring to fig. 1, the antenna system includes a plurality of antennas 10, a switching unit 20, a communication unit 30 and a control unit 40. Each antenna 10 is connected to a switching unit 20. The control unit 40 is connected to the switching unit 20 and the communication unit 30, respectively. The communication unit 30 is also connected to the switching unit 20.

In one embodiment, each antenna 10 is used for transmitting and receiving wireless signals, and further can receive or output data. In fig. 1, 5 antennas 10(101, 102, 103, 104, 105) are illustrated as an example, however, the number of antennas 10 is not limited in the present invention.

In some embodiments, each antenna 10 may be an omni-directional antenna, a directional antenna, or other type of antenna, but is not limited thereto.

referring to fig. 1 and fig. 2A, the switch unit 20 has a plurality of switches 21, and each of the switches 21 corresponds to one of the antennas 10. When the switch 21 is in the on state, the switch 21 is electrically connected to the corresponding antenna 10. When the switch 21 is in the open state, the switch 21 and the corresponding antenna 10 are not conducted. In this embodiment, at least one of the switches 21 in the switching unit 20 is in a conducting state. In the present embodiment, the switches 212 and 213 are turned on, and the other switches 211, 214 and 215 are turned off, but not limited thereto.

The antenna 10 can transmit the received wireless signal to the communication unit 30 through the switch 21 in the on state, or the communication unit 30 can transmit the data to the corresponding antenna 10 through the switch 21 in the on state, so as to further wirelessly output the data.

In one embodiment, the number of switches 21 corresponds to the number of antennas 10. In other words, the sum of the number of antennas 10 is the same as the sum of the number of switches 21. Here, fig. 1 illustrates 5 switches 21(211, 212, 213, 214, 215) as an embodiment, but the number of switches 21 is not limited in the present invention.

In fig. 1, the switches 212 and 213 are turned on, and the other switches 211, 214 and 215 are turned off. Therefore, the antennas 102 and 103 corresponding to the connection switches 212 and 213 transmit the received wireless signals to the communication unit 30.

The communication unit 30 receives the reference value group from the antennas 102 and 103 corresponding to the switches 212 and 213 in the on state in the switching unit 20 (step S01). Then, the communication unit 30 transmits the received reference value group to the control unit 40.

Referring to fig. 1 to 4, the control unit 40 compares the received reference value sets with an alarm threshold to determine whether the reference value sets meet expectations (step S02). When at least one of the reference value sets is determined to be not expected, the control unit 40 outputs a restart command to restart the switching unit 20 (step S03). In the process of restarting the switching unit 20, the switching unit 20 switches all the switches (211 to 215) to the on state (as shown in fig. 3) according to the restart command (i.e., step S031 of fig. 2B). Next, the control unit 40 receives the feedback values from the antennas 10 corresponding to the switches 21 from the communication unit 30 (i.e., step S032 in fig. 2B). A select instruction is generated according to at least one of the return values and sent to the switch unit 20 (i.e., step S033 of fig. 2B). In detail, the control unit 40 sequences all the received feedback values to generate a sequencing result, and selects a preferred one (e.g., the feedback value with the earlier sequencing) of the feedback values according to the sequencing result, and generates a corresponding selection instruction.

After the control unit 40 transmits the selection instruction to the switching unit 20, the switching unit 20 selects the corresponding switch 21 according to the selection instruction and maintains the switch 21 in the on state, and switches the remaining switches 21 to the off state (as shown in fig. 4) (i.e., step S034 of fig. 2B). In this embodiment, referring to fig. 3 to 4, after the control unit 40 sequences all the backhaul values, it can be known that the backhaul values of the antennas 101 and 104 corresponding to the switches 211 and 214 are the top 2 of the antennas corresponding to the five switches 21. Therefore, the control unit 40 can generate a corresponding selection instruction according to the sorting result. The switching unit 20 maintains the switches 211 and 214 in the on state and switches the switches 212, 213 and 215 in the off state according to the selection command.

In some embodiments, the selection command generated by the control unit 40 can select one of the switches 21 to be maintained in the on state, and make the other switches 21 in the off state. In other embodiments, any combination of switches 21 may be selected to form the conducting state. Which can be adjusted according to actual requirements.

when the selection command selects one of the switches 21 to turn on, it indicates that the control unit 40 sorts the return values, selects the best one (the first one) of the sorted results, maintains the switch 21 corresponding to the best return value (i.e., the switch 211-215 corresponding to the best return value) in the on state, and switches the other switches 21 in the off state.

After the control unit 40 sends the selection command, referring to fig. 2A again, the control unit 40 can receive the reference value set of the antennas in the on state from the communication unit 30 after an interval (i.e. repeatedly perform step S01), so that the control unit 40 can determine again whether the reference value set meets the alarm threshold (i.e. perform step S02). When the reference value set is determined not to meet the alarm threshold, the restart command is generated again to restart the switching unit 20 (i.e., step S03).

in an embodiment, the control unit 40 has a plurality of restart time points, that is, the control unit 40 outputs a restart instruction according to the restart time points to drive the switching unit 20 to restart. In the process of restarting the switching unit 20 each time, the control unit 40 records the sorting result of the feedback values of each antenna 10 each time, and analyzes the change of the multiple feedback values of each antenna 10 according to the sorting results. And calculating a time interval between more efficient restart time points based on the change in the return value of each antenna. For example, referring to FIG. 5, the X-axis is the standby time T1, and the Y-axis is the reset time interval T2 of the switch unit 20. In one embodiment, as the standby time becomes longer, the time interval between the restart time points may be increased by a multiple of the time interval Tb (e.g., 30 minutes, 1 hour, 2 hours, etc.). In this embodiment, when the time interval between the predetermined restart time points is 30 minutes, the control unit 40 records the sorting result of each return value every time according to the restart instruction every 30 minutes, and if the sorting result of each sorted return value (e.g. occurring three times) has not changed, the control unit 40 delays to 1 hour after the next (e.g. fourth) predetermined restart time point. On the contrary, if the sequence of the returned values recorded by the control unit 40 at the time of the restart instruction corresponding to the preset restart time point changes, the control unit 40 maintains the preset restart time point to output the restart instruction.

Similarly, as the standby time becomes longer, the time interval between the restart time points may be increased in an exponential manner by the time interval Tc (e.g., 30 minutes, 1.5 hours, 4 hours, etc.), whereby the number of times the switching unit 20 is restarted may be reduced. The operation load of the control unit 40 can be reduced when the antenna system is in a stable environment.

in an embodiment, if the selected antennas are all the same antenna after a plurality of restart steps, the control unit 40 may increase the time interval between the restart time points by setting the time interval to be a multiple of the time interval Tb or the exponential time interval Tc as described above.

In one embodiment, the time interval between the restart time points has a maximum time interval Td. For example, the maximum time interval of the control unit 40 is set to 12 hours. When the control unit 40 increases the preset restart time length in the above manner, the time interval between the restart time points is at most equal to the maximum time interval Td.

Here, the details of the control unit 40 receiving the reference value group and performing the determination will be described below with reference to a plurality of embodiments.

in the first embodiment, referring to fig. 1, the switches 212 and 213 in the switching unit 20 are turned on, and the switches 211, 214 and 215 are turned off. Therefore, the communication unit 30 can receive the reference value sets of the antennas 102 and 103 via the switches 212 and 213, respectively (step S01). The reference value group is the Signal Strength of the wireless signals individually received by the antennas 102 and 103, such as rssi (received Signal Strength indicator) value, Ping value, or other indicators related to the Signal Strength.

in the first embodiment, the reference value set is taken as an RSSI value as an example. When the communication unit 30 receives the wireless signals from the antennas 102 and 103, it obtains a first RSSI value (i.e., a first reference value set) from the wireless signal of the antenna 102 and a second RSSI value (i.e., a second reference value set) from the wireless signal of the antenna 103 (step S01). Then, the communication unit 30 transmits the first reference value group and the second reference value group to the control unit 40. Next, the control unit 40 determines whether any one of the first reference value set and the second reference value set is lower than the alarm threshold (see steps S021 and S022 in fig. 6). That is, the control unit 40 determines the magnitude of the first reference value set (e.g., the first RSSI value is-85 dBm) and a preset alarm threshold (e.g., the preset RSSI value is-80 dBm). In this embodiment, the first set of reference values is less than the alarm threshold. That is, the signal strength of the radio signal received by the antenna 102 is weakened. The control unit 40 generates a restart instruction (step S03). The control unit 40 then transmits a restart instruction to the switching unit 20. The switching unit 20 switches each switch 21 to the on state according to the restart instruction (step S031) (as shown in fig. 3). Then, the control unit 40 receives the corresponding feedback values (RSSI values) of the antennas 10 from the communication unit 30 (step S032), and sorts the feedback values. And selects the switch 21 (the switches 211 and 214 in this embodiment) corresponding to the return value with the highest value according to the sorting result (as shown in fig. 4), so as to generate the selection command (step S033). Therefore, the switching unit 20 maintains the switches 211 and 214 in the on state and switches the switches 212, 213 and 215 in the off state (as shown in fig. 4) according to the selection command (step S034). Otherwise, when the control unit 40 determines that both the first reference value set and the second reference value set and the alarm threshold value are in accordance with the expectation, the control unit 40 does not output the restart instruction. Therefore, the antenna system can maintain good wireless transmission quality, and users can further keep good use feeling.

In one embodiment, when the control unit 40 determines that the first reference value set (e.g., the first RSSI value is-75 dBm) is greater than the alarm threshold, the determination result is satisfactory. The control unit then compares the second reference value set (e.g., the second RSSI value is-85 dBm) with an alarm threshold (e.g., the preset RSSI value is-80 dBm) to determine whether the second reference value set is in accordance with the expectation (see step S022 in fig. 6). In this embodiment, since the determination results of the second reference value set and the alarm threshold are not in agreement, the control unit 40 outputs a restart instruction to the switch unit 20 to restart the switch unit 20 (see step S03 in fig. 6). The switching unit 20 switches each switch 21 to the on state according to the restart command (as shown in fig. 3), and receives the corresponding feedback value (RSSI value) of each antenna 10 for sorting. And can generate the corresponding selection command to drive the corresponding switch 21 to be in the on state and the off state.

The order of judging the reference value set and the alarm threshold is not limited in the present invention. That is, it can be determined whether the second reference value set and the alarm threshold value meet the expectation first, and then it can be determined whether the first reference value set and the alarm threshold value meet the expectation.

Referring to fig. 1 and 2A, in one embodiment, the reference value set includes a front reference value and a rear reference value, and the warning threshold value may be a reduction degree of the signal strength. Taking the first embodiment as an example, the alarm threshold may be the degree of decrease of the RSSI value. That is, the control unit 40 obtains the RSSI value (i.e., the previous reference value is-69 dBm) of the antenna 102 corresponding to the switch 212 in the on state at the first time point (the earlier time point), and obtains the RSSI value (i.e., the next reference value is-75 dBm) of the antenna 102 corresponding to the switch 212 in the same on state at the second time point (the later time point). Then, a difference between the front reference value and the rear reference value (e.g., a difference obtained by subtracting the front reference value from the rear reference value) is calculated, and the difference is compared with an alarm threshold to determine whether the difference meets the expectation. For example, the preset alarm threshold is-5 (i.e., the RSSI reduction degree is preset to be 5). When the difference between the current reference value and the later reference value (for example, the difference is-6) is smaller than the alarm threshold (indicating that the RSSI value of the antenna 102 decreases by more than 5), that is, indicating that the signal strength of the wireless signal received by the antenna 102 is weakened. The control unit 40 then outputs a restart instruction to restart the switching unit 20.

In one embodiment, when the reference value set received by the communication unit 30 is the Ping value of the wireless signal, it can be determined whether the reference value sets and the alarm threshold are expected to be matched. That is, when the control unit 40 determines that any one of the Ping values is greater than the alarm threshold, it generates a restart instruction. On the contrary, when the Ping values are determined to be less than or equal to the alarm threshold, it indicates that the antenna 10 of the switch 21 corresponding to the on state has good wireless transmission quality, and the user can further keep good use feeling. In some embodiments, other methods for determining the signal strength are the same as above, and are not described herein again.

in one embodiment, when the feedback values (e.g., RSSI values) of the antennas 10 received by the control unit 40 are not compared with the warning threshold value during the restart of the switching unit 20, in order to enable the antenna system to continue communication, the antenna 10 with the better feedback value is selected from all the non-expected feedback values for communication, which may cause the problem that the switching unit 20 is always restarted.

Therefore, when the switching unit 20 is continuously restarted for several times (e.g., 3 times) each time the RSSI value (received by the control unit 40) of each antenna 10 does not meet the expected comparison with the alarm threshold, an alarm threshold adjustment procedure is initiated.

In one embodiment, the alarm threshold adjustment procedure is that the control unit 40 adjusts the alarm threshold to be the best one of the echo values of the antennas 10, or adjusts the alarm threshold to be the best echo value by one difference (e.g., the difference is 5, i.e., the alarm threshold is decreased), so as to avoid that all the antennas 10 do not meet the expectation compared with the alarm threshold in the current environment, which results in the switching unit 20 being restarted and unnecessary system load.

Referring to fig. 1 and 2A, in one embodiment, the communication unit 30 uses the connection time of the antenna 102 extracted from the received wireless signal as a reference value set. I.e., the period during which the antenna 102 transmits radio signals is called the link time. In this embodiment, the control unit 40 sets a predetermined connection time as the alarm threshold. Next, the control unit 30 compares the connection time with a predetermined connection time (i.e., step S02), and outputs a restart command when the connection time is less than the predetermined connection time (i.e., step S03). In this embodiment, when the connection time is suddenly reduced due to an instantaneous interruption or abnormality of the antenna 102, it can indicate that the wireless communication quality of the antenna 102 is poor, so that the switching unit 20 is restarted to select an antenna with better wireless communication quality, so that the user can keep a good use experience.

Referring to fig. 1 again, the control unit 40 further includes a sensing module 41, and the sensing module 41 includes a positioning element 411 capable of communicating with a Global Positioning System (GPS) to obtain current positioning information as a reference value set. In this embodiment, the control unit 40 sets the previous positioning information as the alarm threshold and compares the current positioning information with the previous positioning information. If the current positioning information is different from the previous positioning information (i.e. the reference value group does not meet the expectation), the antenna system is judged to have the moved position. Thus, the control unit 40 generates a restart command to restart the switching unit 20.

In one embodiment, the sensing module 41 includes a gravity sensing element 412, which can sense whether the antenna system has dynamic changes such as turning, moving, angle changing or other arbitrary changes, so as to generate a current gravity sensing information as a system status reference value. In this embodiment, the control unit 40 sets the previous gravity sensing information as the alarm threshold, and compares the current gravity sensing information with the previous gravity sensing information. If the current gravity sensing information is different from the previous gravity sensing information (i.e. it indicates that the system state reference value is not in accordance with the expectation), it is determined that the antenna system has dynamic changes such as flipping, moving, angle change, or other arbitrary changes. Thus, the control unit 40 generates a restart command to restart the switching unit 20.

In one embodiment, the gravity sensing element 412 may be a gravity Sensor (G-Sensor), a gyroscope, or a combination thereof, which is not limited in the present invention.

according to the above embodiment, the switching unit 20 can be further restarted to drive the switches 21 to change to the off state or the on state again by comparing the reference value set of each antenna 10 with the alarm threshold value. Therefore, each antenna 10 can be suitable for maintaining a proper radiation pattern at any time, so that good wireless transmission quality can be maintained at any time, and users can further keep the use feeling. Furthermore, the alarm threshold value can be changed intelligently, so that each switch 21 can be switched accurately and the user can obtain better use feeling.

The above-described embodiments and/or implementations are only for illustrating the preferred embodiments and/or implementations of the present technology, and are not intended to limit the implementations of the present technology in any way, and those skilled in the art may make modifications or changes to other equivalent embodiments without departing from the scope of the technical means disclosed in the present disclosure, but should be construed as the technology or implementations substantially the same as the present technology.