JP2019029705A - Reception sensitivity control apparatus, reception sensitivity control method, and reception sensitivity control program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve reception sensitivity regardless of how to hold a mobile terminal having a metal housing. SOLUTION: A GND contact for grounding a metal housing 105 provided on a housing of a mobile terminal at a plurality of different places, and switches SW1 to SW4 provided on the GND contact corresponding to each way of holding the housing when hand-held. The CPU 101 is provided for switching and controlling the above. In addition, switching between the tilt detection unit 103 that detects a plurality of orientations of the housing and the switches of a plurality of GND contacts having good reception characteristics for each of the plurality of orientations of the housing corresponding to each way of holding the housing. The CPU 101 has a SW table 111 in which the state is set, and the CPU 101 refers to the SW table 111 and grounds the GND contact corresponding to the detected orientation of the housing when the mobile terminal is actually used. [Selection diagram] Fig. 1

Description

  The present invention relates to a reception sensitivity control apparatus, a reception sensitivity control method, and a reception sensitivity control program for improving the reception sensitivity of a mobile terminal.

  In recent mobile terminals, for example, smartphones, due to improvements in design, etc., those in which metal is provided on the entire outer periphery of the housing, or those in which metal is partially provided instead of resin are used. Since the antenna built in such a portable terminal is affected by the metal used for the housing, the influence of the metal is reduced by grounding the metal portion with respect to the built-in substrate. If unnecessary resonance of the metal part occurs in the communication band used due to a change in how the user holds the mobile terminal, the antenna performance deteriorates and the reception performance deteriorates.

  As a conventional technique, there is a technique for controlling the high-frequency current flowing through the ground by switching between the ground of the substrate and the metal conductor with a switch and maintaining the antenna characteristics in different communication bands (for example, see Patent Document 1 below). .) In addition, there is a technique for adjusting a matching state of an antenna by detecting a plurality of ways of holding a mobile terminal (for example, see Patent Document 2 below).

JP 2013-074361 A Japanese Patent Laying-Open No. 2015-207812

  However, since the frequency of unnecessary resonance of the metal portion differs between when the mobile terminal is in free space and when it is handheld, only the antenna matching constant cannot be adjusted. In the adjustment of the matching constant of the antenna, although the radiation efficiency of the antenna can be lowered and the transmission power can be lowered, the metal other than the antenna does not resonate and the frequency of the unnecessary resonance cannot be changed. Thereby, unnecessary resonance occurs in the metal portion, and the influence on the antenna when the reception sensitivity is deteriorated cannot be reduced.

  In one aspect, an object of the present invention is to improve reception sensitivity regardless of how to hold a mobile terminal having a metal casing.

  In one proposal, the reception sensitivity control device corresponds to the GND contact for grounding the metal casing provided in the casing of the mobile terminal at a plurality of different locations, and for each holding method when the casing is held. And a control unit that switches and controls a switch provided at the contact point.

  According to one embodiment, there is an effect that reception sensitivity can be improved regardless of how to hold a mobile terminal having a metal casing.

FIG. 1 is a diagram illustrating a hardware configuration example of a reception sensitivity control apparatus according to the embodiment. FIG. 2 is a front view of an example of a portable terminal provided with the reception sensitivity control apparatus according to the embodiment. FIG. 3 is a cross-sectional view showing an example of a grounding structure of a metal casing of a portable terminal according to an existing technology. FIG. 4 is a chart for explaining countermeasures against unnecessary resonance of an antenna caused by grounding a metal casing according to existing technology. (Part 1) FIG. 5 is a chart for explaining countermeasures against unnecessary resonance of an antenna due to grounding of a metal casing according to existing technology. (Part 2) FIG. 6 is a chart for explaining countermeasures against unnecessary resonance of an antenna caused by grounding a metal casing according to existing technology. (Part 3) FIG. 7 is a diagram for explaining the resonance of the antenna. FIG. 8 is a cross-sectional view for explaining a plurality of grounding structures of the metal casing of the reception sensitivity control apparatus according to the embodiment. FIG. 9 is a diagram illustrating a circuit configuration example of the ground switching SW of the reception sensitivity control apparatus according to the embodiment. FIG. 10 is a cross-sectional view illustrating grouping of a plurality of GND contacts used for SW setting of the reception sensitivity control apparatus according to the embodiment. FIG. 11A is a front view illustrating a plurality of holding methods used for SW setting of the reception sensitivity control apparatus according to the embodiment. (Part 1) FIG. 11B is a front view illustrating a plurality of holding methods used for SW setting of the reception sensitivity control apparatus according to the embodiment. (Part 2) FIG. 11C is a front view illustrating a plurality of holding methods used for SW setting of the reception sensitivity control apparatus according to the embodiment. (Part 3) FIG. 12 is a chart illustrating SW settings of the reception sensitivity control apparatus according to the embodiment. FIG. 13 is a flowchart illustrating a pre-tuning process example performed by the reception sensitivity control apparatus according to the embodiment. FIG. 14 is a table showing a level range setting table used in actual use tuning of the reception sensitivity control apparatus according to the embodiment. FIG. 15 is a flowchart illustrating a processing example of actual use tuning performed by the reception sensitivity control apparatus according to the embodiment. FIG. 16A is a flowchart illustrating the contents of coarse tuning processing during actual use performed by the reception sensitivity control apparatus according to the embodiment. (Part 1) FIG. 16B is a flowchart illustrating the processing contents of coarse tuning during actual use performed by the reception sensitivity control apparatus according to the embodiment. (Part 2) FIG. 17 is a flowchart of the fine tuning processing performed during actual use performed by the reception sensitivity control apparatus according to the embodiment. FIG. 18 is a diagram illustrating a GND grounding structure example of the ground switching SW of the reception sensitivity control apparatus according to the embodiment. (Part 1) FIG. 19 is a diagram illustrating a GND grounding structure example of the ground switching SW of the reception sensitivity control apparatus according to the embodiment. (Part 2) FIG. 20 is a diagram illustrating a GND ground structure example of the ground switching SW of the reception sensitivity control apparatus according to the embodiment. (Part 3)

(Embodiment 1)
FIG. 1 is a diagram illustrating a hardware configuration example of a reception sensitivity control apparatus according to the embodiment. The reception sensitivity control apparatus 100 is provided in a mobile terminal that can be carried by a user, such as a smartphone or a mobile phone. FIG. 1 mainly shows a configuration relating to reception sensitivity control of the mobile terminal.

  The reception sensitivity control apparatus 100 includes a CPU 101, a memory 102, an inclination detection unit 103, and a ground changeover switch (SW) 104. Reference numeral 105 denotes a metal portion (metal casing) of the casing of the mobile terminal. As described above, the metal housing 105 is a portion that touches the user's hand when the user holds the mobile terminal, such as a side surface of the mobile terminal, and the metal housing 105 depends on how the user holds the mobile terminal. The position where the hand touches 105 changes, not fixed.

  The CPU 101 functions as a control unit that performs processing related to reception sensitivity control. The CPU 101 may use a CPU for executing applications and the like that the mobile terminal has, and may also be configured to execute control of reception sensitivity according to the embodiment. The CPU 101 controls the ground switching SW 104 to ground and connect the metal casing 105 of the mobile terminal to one of the GNDs of a plurality of substrates provided inside the mobile terminal. The CPU 101 switches and controls the ground switching SW 104 with reference to the SW table 111 of the memory 102.

  The metal casing 105 having a predetermined length is grounded at one of a plurality of positions or a plurality of combined positions by the ground switching SW 104. In the example of FIG. 1, the metal casing 105 is grounded by the ground switching SW 104 at n different positions along the length direction. The metal housing 105 is provided at a location where the user's hand touches, and the location where the user touches the metal housing 105 differs depending on how the mobile terminal is held. Therefore, the GND ground location is set to a plurality of different locations.

  The memory 102 stores and holds as the SW table 111 the switching state of the ground switching SW 104 that performs GND grounding suitable for each pattern of how the user holds the mobile terminal. The SW table 111 is set by pre-tuning before operation of the mobile terminal (details will be described later). The memory 102 can be configured using a ROM, a RAM, or the like. For example, the SW table 111 is set and stored in a nonvolatile memory.

  The inclination detection unit 103 detects an inclination including the orientation (up / down / left / right) of the mobile terminal. The inclination is, for example, an acceleration sensor that can detect three axial directions of front and rear X, left and right Y, and upper and lower Z, a geomagnetic sensor that can detect east, west, north and south, or a combination of an acceleration sensor and a gyro sensor that can detect the rotation speed It can be detected using the sensor 112. As the 6-axis sensor, a sensor generally mounted on a mobile terminal can be used.

  FIG. 2 is a front view of an example of a portable terminal provided with the reception sensitivity control apparatus according to the embodiment. A smartphone is shown as the mobile terminal 200. A display unit 202 is provided on the front surface of the casing 201 of the portable terminal 200. The metal casing 105 described above is provided on both sides of the casing 201.

  In addition, antennas 203 are provided inside and below the casing 201, respectively. As for the antenna 203, an antenna (800 MHz band) 203a and an antenna (2 GHz band) 203b of different frequency bands are respectively provided above and below. For example, the antenna 203 (203a, 203b) provided in the lower part is a main antenna used for transmission / reception of wireless communication, and the antenna 203 (203a, 203b) provided in the upper part is a sub-antenna used for diversity reception. .

(Example of grounding structure of existing metal housing and unnecessary resonance countermeasures)
FIG. 3 is a cross-sectional view showing an example of a grounding structure of a metal casing of a portable terminal according to an existing technology. Here, an example of the grounding structure of the metal casing according to the existing technology will be described. Since the antenna 203 (see FIG. 2) of the portable terminal 200 is affected by the metal casing 105 used as a part of the casing 201, the metal casing 105 is used as substrates (circuit boards) 301a and 301b of the casing 201. The ground (GND) is grounded to reduce the influence of the metal casing 105.

  In the example of FIG. 3, the metal casing 105 provided along the vertical direction of both sides of the casing 201 is grounded to the circuit board 301 a via the GND contact 303. A battery (battery) 302 is provided at the center of the housing 201, and substrates 301 a and 301 b are provided above and below the battery 302, respectively. The GND contact 303 is disposed at the GND terminal portion of the substrates 301a and 301b, and grounds the metal housing 105 to the GND terminal.

  4 to 6 are diagrams for explaining countermeasures against unnecessary resonance of an antenna due to grounding of a metal casing according to existing techniques. 4A to 6A, the horizontal axis represents frequency, the vertical axis represents reflection loss (S11), and λ represents a communication frequency band. 4B to 6B are enlarged views of FIG. 4A, where the horizontal axis represents frequency and the vertical axis represents antenna efficiency. A broken line in the figure is a normal characteristic, for example, a characteristic of the casing 201 not using the metal casing 105.

  A solid line in the figure is an unnecessary resonance characteristic, for example, a characteristic in the case where the metal casing 105 is used as a part of the casing 201, and an unnecessary resonance deviating from the normal characteristic occurs as indicated by a location X. However, in the example shown in FIG. 4, the ground X of the metal housing 105 can be grounded so that the unnecessary resonance point X can be released outside the communication frequency band λ.

  FIG. 5 is a chart for explaining unnecessary resonance of the antenna that occurs in the grounding structure of the metal casing of the existing technology. Even if the metal case 105 described with reference to FIG. 4 is grounded, depending on how the user holds the case 201 of the mobile terminal 200, the unnecessary resonance point X of the metal case 105 may cause a communication frequency to be used. It may occur by moving within the band λ.

  For example, the frequency of unnecessary resonance by the metal casing 105 differs between when the mobile terminal 200 is in free space and when the user holds the mobile terminal 200 by hand. The free space is a state where the user does not hold the mobile terminal 200 such as a state where the mobile terminal 200 is placed. Moreover, if the hand-held state with respect to the portable terminal 200 is different, the frequency of unnecessary resonance by the metal casing 105 is different.

  Due to the occurrence of this unnecessary resonance, as shown in FIG. 5 (b), the antenna has a characteristic in which the generation of unnecessary resonance (solid line) within the communication frequency band λ is partially lost with respect to the normal characteristic (broken line). Efficiency decreases and reception characteristics deteriorate.

  FIG. 6 is a chart for explaining an example of countermeasures against unnecessary resonance of the antenna that occurs in the ground structure of a metal casing according to the existing technology. As described above, since the frequency of the unnecessary resonance of the metal portion differs between when the mobile terminal 200 is in free space and when it is handheld, there is a limit to adjustment using only the matching constant of the antenna according to the existing technology. As shown in FIG. 6A, even if the matching constant of the antenna is changed, the unnecessary resonance frequency (location X) of the metal casing 105 is not changed only by moving the pole of the resonance frequency. And as shown in FIG.6 (b), the radiation efficiency of an antenna cannot be improved.

  As measures for improving the unnecessary resonance frequency, for example, there is an antenna tuning device that reduces variations in the impedance of the antenna with respect to a minute change. However, since expensive components are used, unnecessary resonance cannot be realized at low cost. The tuning device changes the antenna matching circuit constant to move the antenna resonance frequency pole. Therefore, the unnecessary resonance frequency of the metal casing 105 does not change no matter how much the antenna matching circuit is adjusted, so that the antenna performance does not improve, and when the unnecessary resonance frequency moves within the communication frequency band λ used, It is necessary to move the frequency of the unwanted resonance itself.

  Here, as in the technique of Patent Document 1 described above, the frequency of unnecessary resonance cannot be changed by a technique in which one switch is provided at the antenna feeding point and the connection with the conductor is switched for each frequency. And the influence of an antenna when unnecessary resonance occurs in the metal casing 105 cannot be reduced. In addition, as in the technique of Patent Document 2, a configuration in which a plurality of grip sensors are provided in the terminal to sense how the terminal is held by the user and the variable capacitance element in the matching circuit is controlled, reduces the radiation efficiency of the antenna. It only reduces the transmission power. In this case, unnecessary resonance of the metal casing 105 other than the antenna enters the communication frequency band λ, and the reception sensitivity is deteriorated.

(Example of grounding structure of metal casing and countermeasure for unnecessary resonance)
The unnecessary resonance described above occurs when the metal casing 105 appears as an antenna. FIG. 7 is a diagram for explaining the resonance of the antenna. FIG. 7A is an equivalent circuit diagram of the antenna 203. FIG. 7B is a chart showing antenna characteristics, where the horizontal axis represents frequency and the vertical axis represents current. When a high frequency is applied to the antenna circuit composed of L (inductor), C (capacitance), and R (resistance) in FIG. 7A, a high frequency is obtained at a frequency (f ₀ ) determined by each value of LCR shown in FIG. 7B. The value of current increases.

  When the user's hand touches the metal casing 105, the value of C (capacitance) changes and the resonance frequency changes. On the other hand, the resonance frequency also changes depending on the length of the antenna 203.

  For this reason, in the embodiment, the GND grounding position is changed depending on the state change of the mobile terminal 200, that is, when the mobile terminal 200 is held by hand and in free space. Thereby, the frequency of the unnecessary resonance is changed, and the unnecessary resonance is moved out of the communication frequency band λ. As a specific means for changing the GND ground position, a plurality of GND contacts are provided in the metal casing 105 portion.

  FIG. 8 is a cross-sectional view for explaining a plurality of grounding structures of the metal casing of the reception sensitivity control apparatus according to the embodiment. As shown in FIG. 8, the metal casing 105 provided along the vertical direction of both sides of the casing 201 is grounded to the circuit boards 301a and 301b via a plurality of GND contacts 303a to 303j.

  One (right side) metal casing 105 is grounded to the upper circuit board 301a through three GND contacts 303a to 303c, and is grounded to the lower circuit board 301b through two GND contacts 303d and 303e. .

  The other (left side) metal casing 105 is grounded to the upper circuit board 301a via three GND contacts 303f to 303h, and is grounded to the lower circuit board 301b via two GND contacts 303i and 303j. .

  The plurality of GND contacts 303 (303a to 303j) correspond to SW1 to SW10 shown in FIG. 1, and a position for grounding GND is selected by switching the ground switching SW104. The CPU 101 controls the switching of the ground switch SW104. As described above, a plurality of GND ground positions are provided for the metal housing 105, and the GND ground position is switched by the ground switching SW 104, whereby the resonance frequency is changed and the optimal GND for the hand-held position where the mobile terminal 200 changes is always optimal. The grounding state can be obtained.

  FIG. 9 is a diagram illustrating a circuit configuration example of the ground switching SW of the reception sensitivity control apparatus according to the embodiment. Each switch (SW1 to SW10) 900 of the ground switching SW 104 includes a port 1 (901) for connecting to the metal casing 105 and a port 2 (902) for grounding to the GND of the circuit board 301 (301a, 301b). It has.

  Open or short of each switch (SW1 to SW10) 900 is controlled by control signals (VCNT1 to VCNT10) from the CPU 101. Then, the metal casing 105 of the switch (SW1 to SW10) 900 part subjected to the short control is grounded via the GND contact 303 (303a to 303j).

  Ideally, the metal casing 105 is grounded to the circuit board 301 (301a, 301b) at an interval of λ / 4 or less. In the structure of the portable terminal 200 described in FIG. 8 and the like, since the battery 302 is mounted between the two circuit boards 301a and 301b, the metal casing 105 positioned at the battery 302 cannot be grounded to GND. In addition, with the recent increase in the size of the battery 302, the distance at which GND grounding cannot be achieved may exceed λ / 4. In this case, this portion of the metal housing 105 where GND cannot be installed is virtually seen as an antenna. For this reason, the distance between the GND contacts 303 (303a to 303j) provided on the circuit board 301 is set to λ / 8 or less of the maximum frequency used for communication so that the adjustment can be made at least half of the antenna length.

  CPU101 discriminate | determines degradation of a receiving sensitivity when a user holds the portable terminal 200 using RSRP and RSRQ. RSRP is an abbreviation for Reference Signal Received Power, and RSRQ is an abbreviation for Reference Signal Received Quality.

  Further, the CPU 101 detects the inclination of the mobile terminal 200 based on the information of the 6-axis sensor 112 in the mobile terminal 200 and selects (changes) the optimal GND grounding position of the metal housing 105 based on the information. Thus, the antenna reception sensitivity is controlled to be good.

  The above-described SW setting of the GND grounding position of the metal casing 105 is performed by using pre-tuning for finding the optimum SW setting condition depending on how the mobile terminal 200 is held, and the result of the pre-tuning while actually using the mobile terminal 200. It can be divided into actual use tuning. These tunings will be described.

(Pre-tuning)
Setting all SW settings of the ground switching SW 104 during actual use takes time, and depending on the SW setting, reception sensitivity may be deteriorated. For this reason, in the pre-tuning, the optimum SW setting (SW table 111) depending on how the portable terminal 200 is held is set in the memory 102 of the portable terminal 200.

  In the example shown in FIG. 2, the mobile terminal 200 is provided with four antennas 203 (203a, 203b) at different positions. Depending on how the portable terminal 200 is held, how the antennas 203 are affected varies. For this reason, as shown in FIG. 10, the GND contacts 303 that are close to each other (close to each other) are divided into four groups as one group.

  FIG. 10 is a cross-sectional view illustrating grouping of a plurality of GND contacts used for SW setting of the reception sensitivity control apparatus according to the embodiment. In the SW table 111, SW group information for each SW (SW1 to SW10) of the ground switching SW104 is set.

  SW1 to SW3 of three GND contacts 303a to 303c that are located on the right side of the circuit board 301a and are close to each other are referred to as SW group 1. Also, SW4 and SW5 of two GND contacts 303d and 303e that are located on the right side of the circuit board 301b and are close to each other are referred to as SW group 2. In addition, SW groups SW6 to SW8 of the three GND contacts 303f to 303h that are located on the left side of the circuit board 301a and are close to each other are referred to as SW group 3. In addition, SW groups SW <b> 9 and SW <b> 10 of the two GND contacts 303 i and 303 j that are located on the left side of the circuit board 301 b and are close to each other are referred to as SW group 4.

  FIG. 11A to FIG. 11C are front views illustrating a plurality of holding methods used for SW setting of the reception sensitivity control apparatus according to the embodiment. As shown in these drawings, the general holding method of the mobile terminal 200 is set in the SW table 111 for each case.

  CASE 1 in FIG. 11A (a) is a case where the lower side of the portable terminal 200 is held vertically with the left hand. CASE 2 in FIG. 11A (b) is a case where the lower side of the portable terminal 200 is vertically held with the right hand. CASE 3 in FIG. 11B (c) is a case where the mobile terminal 200 having the right side is held with both hands. CASE 4 in FIG. 11B (d) is a case where the mobile terminal 200 whose left side is the upper side is held with both hands. CASE 5 in FIG. 11C (e) is a case where the upper side of the upside down portable terminal 200 is vertically held (held) with the left hand. CASE 6 in FIG. 11C (f) is a case where the upper side of the upside down portable terminal 200 is vertically held (held) with the right hand.

(Pre-tuning)
FIG. 12 is a chart illustrating SW settings of the reception sensitivity control apparatus according to the embodiment. An example of items set in the pre-tuning in the SW table 111 is shown. The SW table 111 is created for each frequency band to be used.

  The SW table 111 shown in FIG. 12 includes, as items for holding in the vertical direction, [initial state] (that is, a state where the portable terminal 200 is horizontally placed flat on a table or the like without holding the portable terminal 200), and the portable terminal 200 The holding method is provided for each case (CASE1 to CASE6). Further, as each item in the horizontal direction, each GND contact 303 (303a to 303i) is provided for each SW group. Also, the RSRP and RSRQ values detected for each case (CASE) are set and held.

  The CPU 101 sets an optimum GND grounding position by combining SWs for different holding methods set in the SW table 111 as processing that can be performed by pre-tuning. At this time, the CPU 101 turns on and off all the switches (SW1 to SW10) 900. Then, the combination of ON / OFF of the switch 900 when the optimum RSRP and RSRQ values are detected and the RSRP and RSRQ values are written and held in the SW table 111. The value “1” is a short (closed) state of the switch 900, and “0” is an open (open) state.

FIG. 13 is a flowchart illustrating a pre-tuning process example performed by the reception sensitivity control apparatus according to the embodiment. An example of pre-tuning processing executed by the CPU 101 before actual use of the mobile terminal 200 is shown. In the pre-tuning, all combinations (10 ¹⁰ types) of the switches SW (SW1 to SW10) are selected depending on how the portable terminal 200 is held, and the RSRP and RSRQ values at the time of each selection are temporarily stored in the memory 102. To do.

  The CPU 101 executes processing for each holding method of the mobile terminal 200 according to the setting of the SW table 111 (step S1301). First, all processes up to step S1307 are executed in [initial state], then the process of CASE1 is executed, and finally the process of CASE6 is executed.

  In the process for each holding method, the holding condition is “initial state” and the SW settings of all SW1 to SW10 are set to the initial value [0000000] (step S1302), and the values of RSRP and RSRQ detected at that time are set. Temporary storage is performed in the memory 102 (step S1303). [0000000] means the open / close state of each switch SW (SW1 to SW10) with 10 bits, and "1" of each bit means the short (closed) state of the corresponding switch SW (SW1 to SW10). “0” means an open state of the corresponding switch SW (SW1 to SW10).

  Then, the CPU 101 determines whether all SW combinations have been completed (step S1304). If the SW setting is [1111111111], it is determined that the process is finished. Initially, the CPU 101 determines that the process has not been completed (step S1304: No), sequentially increments the SW setting from the lower bit (+1), returns [0000000001], and returns to step S1302. Then, the RSRP and RSRQ values detected at this time are temporarily stored in the memory 102 (step S1303). The CPU 101 repeats until the end condition SW setting [1111111111] is reached.

  Then, when the measurement with all combinations of SW settings is completed (step S1304: Yes), the CPU 101 reads out the best RSRP and RSRQ values detected so far from the memory 102 (step S1305). Then, the CPU 101 writes the open / closed state (bit 0/1) of the SW corresponding to the SW setting at which the read best values of RSRP and RSRQ are detected in the SW table 111 shown in FIG. 12 (step S1306).

  For example, the best values of RSRP and RSRQ in [CASE 1] of FIG. 12 are “−108” and “−10”, respectively. The open / close state of each SW when the best value is obtained is that SW1 to SW8 are “ 1 "(short), SW9 and SW10 are" 0 "(open).

  Next, the CPU 101 determines whether all the conditions for holding the portable terminal 200 ([initial state] to [CASE6] have been completed (step S1307). When only the processing relating to the above [initial state] has been completed) (Step S1307: No), the process returns to Step S1301, and next, the process related to [CASE1] is executed, and then the CPU 101 repeats the same process from [CASE2] to [CASE6]. If the processes related to all the conditions ([CASE1] to [CASE6]) are completed (step S1307: Yes), it is determined that all the holding processes have been completed (step S1308), and the above pre-tuning process is terminated. To do.

  Accordingly, the SW table 111 shown in FIG. 12 holds the SW setting for each holding method and the RSRP and RSRQ values (best values) based on the SW setting, and the SW table 111 is completed.

(Real use tuning)
Next, tuning in actual operation of the mobile terminal 200 will be described. When the mobile terminal 200 is actually used, the SW setting of the SW table 111 obtained by pre-tuning is referred to, and the tuning process is performed using the values of RSRP and RSRQ detected at the time of actual use.

  FIG. 14 is a table showing a level range setting table used in actual use tuning of the reception sensitivity control apparatus according to the embodiment. In the level range setting table 1401 shown in FIG. 14, the horizontal axis is RSRQ, and the vertical axis is RSRP. In the setting example of FIG. 14, the combination of RSRQ and RSRP values is divided into five stages according to ranges (Range 1 to Range 5). Range 1 is the level with the strongest electric field, and becomes the level of the weak electric field as Range 2 → Range 5. In addition, NG is a level equivalent to out of service area. The level range setting table 1401 is set and stored in the memory 102 in advance, and is referred to by the CPU 101 when tuning the actual use of the mobile terminal 200.

  FIG. 15 is a flowchart illustrating a processing example of actual use tuning performed by the reception sensitivity control apparatus according to the embodiment. The processing content which CPU101 performs at the time of actual use of the portable terminal 200 is shown. When the mobile terminal 200 is actually used, the levels of RSRP and RSRQ vary depending on the radio wave environment. Therefore, the CPU 101 first confirms the RSRP and RSRQ levels during actual use (current) (step S1501).

  Next, the CPU 101 reads the level range setting table 1401 (see FIG. 14). Then, it is determined whether or not the current RSRP and RSRQ levels are different ranges (there is a large change) with respect to the range setting composed of the RSRP and RSRQ values set in the level range setting table 1401 (step) S1502).

  Here, only when the current RSRP and RSRQ levels change by one or more steps with respect to the ranges of the level range setting table 1401 (step S1502: Yes), the tuning operation (1) is performed next (step S1504). On the other hand, if there is no range change (step S1502: No), the current state is maintained, no tuning operation is performed (step S1503), and the process ends. When this tuning operation is not performed, each SW1 to SW10 is set according to the SW table 111 obtained by the pre-tuning.

  In the tuning operation (1) in step S1504, the CPU 101 starts coarse tuning when a range change occurs during actual use (step S1504). In coarse tuning, the information of the inclination detected by the 6-axis sensor 112 is obtained, and the SW group of each SW to be referred to is determined from the SW table 111 (step S1505).

  Next, the CPU 101 performs fine tuning of the tuning operation (2) (step S1506). In this fine tuning, the fine tuning operation is performed by changing only the setting of the SW group that has changed from the initial setting with the settings (CASE 1 to 6) determined in the coarse tuning. In this fine tuning, tuning corresponding to how the user holds the mobile terminal 200 in actual use is performed.

  Next, the CPU 101 reads the SW setting of the best RSRP and RSRQ values in the SW group and compares them with the RSRP and RSRQ values before fine tuning. Then, it is determined whether or not the result (RSRP, RSRQ level) by the fine tuning operation has been improved (step S1507). If the result of fine tuning is improved (step S1507: Yes), the result of fine tuning is adopted, and the fine tuning operation is terminated. On the other hand, if the values of RSRP and RSRQ are not improved (step S1507: No), the SW setting is changed to the original state (before fine tuning) (step S1508), and fine tuning is terminated.

  In coarse tuning, when tuning operation of all SW combinations is performed during actual use, in addition to taking time, there is also a combination in which sensitivity deteriorates from the current state. In order to prevent these effects, an inclination including the current orientation (up, down, left and right) of the mobile terminal 200 is acquired from the six-axis sensor 112, and the target is obtained from the SW table 111 acquired in advance based on the acquired inclination of the mobile terminal 200. In case of holding (CASE). This prevents sensitivity deterioration during actual use due to shortening of the tuning time and unintentional SW setting.

  FIG. 16A and FIG. 16B are flowcharts illustrating processing contents of coarse tuning during actual use performed by the reception sensitivity control apparatus according to the embodiment. Details of the process of step S1504 of FIG. 15 are shown. In coarse tuning, the CPU 101 acquires whether the mobile terminal 200 is tilted (orientated) from the information of the six-axis sensor 112, which is up, down, left, or right (step S1601). Then, the CPU 101 selects a corresponding holding method (CASE) from the SW table 111 according to the obtained orientation of the mobile terminal 200.

  When the orientation of the portable terminal 200 is horizontal (both hands are held), it is determined whether the direction is (1) (step S1602) or (2) (step S1604) according to the vertical direction. In step S1602, the CPU 101 determines that the orientation of the mobile terminal 200 is CASE3 (see FIG. 11B (c)) (step S1603), and ends the process. In step S1604, the CPU 101 determines that the orientation of the mobile terminal 200 is CASE4 (see FIG. 11B (d)) (step S1605), and ends the process.

  Further, when the portable terminal 200 is vertical, it is not possible to obtain information on which hand is held by the left or right hand only by information on the orientation of the six-axis sensor 112. For this reason, when the orientation of the mobile terminal 200 is vertical, the mobile terminal 200 is in a normal vertical position (1) (step S1611), or the mobile terminal 200 is upside down (2) (step S1621). Do one of the other processing.

  When the portable terminal 200 is in the normal vertical position (1) (step S1611), it is either CASE 1 or 2 (see FIGS. 11A (a) and (b)). The CPU 101 first selects CASE 1 (step S1612) and measures the values of RSRP and RSRQ (step S1613). Next, CASE2 is selected (step S1614), and the values of RSRP and RSRQ are measured (step S1615).

  Then, the CPU 101 compares the RSRP and RSRQ values in CASE1 with the RSRP and RSRQ values in CASE2 (step S1616). As a result of comparison, the better (higher) value of RSRP and RSRQ is the result of coarse tuning. If the RSRP and RSRQ values of CASE1 are higher in step S1616 (step S1616: CASE1 is higher), CASE1 is selected (step S1617), and the above processing is terminated. On the other hand, if the RSRP and RSRQ values of CASE2 are higher in step S1616 (step S1616: CASE2 is higher), CASE2 is selected (step S1618), and the above processing ends.

  When the portable terminal 200 is vertical and the vertical position is reversed (2) (step S1621), it is one of CASE5 and 6 (see FIGS. 11C (e) and (f)). The CPU 101 first selects CASE 5 (step S1622), and measures the values of RSRP and RSRQ (step S1623). Next, CASE 6 is selected (step S1624), and the values of RSRP and RSRQ are measured (step S1625).

  Then, the CPU 101 compares the RSRP and RSRQ values in CASE 5 with the RSRP and RSRQ values in CASE 6 (step S1626). As a result of comparison, the better (higher) value of RSRP and RSRQ is the result of coarse tuning. If the values of RSRP and RSRQ for CASE5 are higher in step S1626 (step S1626: CASE5 is higher), CASE5 is selected (step S1627), and the above processing ends. On the other hand, if the RSRP and RSRQ values of CASE6 are higher in step S1626 (step S1626: CASE6 is higher), CASE6 is selected (step S1628), and the above processing is terminated.

  FIG. 17 is a flowchart of the fine tuning processing performed during actual use performed by the reception sensitivity control apparatus according to the embodiment. Details of the process of step S1506 of FIG. 15 are shown. First, the CPU 101 reads a result of coarse tuning by the process shown in FIG. 16 (step S1701). Here, the CPU 101 sets all SW groups (SW groups 1 to 4) to be fine-tuned from the SW table 111, and SW setting values (initial values) stored in the switches (SW1 to SW10) of each SW group. Read “0/1”.

  Next, the switches SW in the read SW group are sequentially switched (step S1702). Then, the RSRP value and the RSRQ value obtained in the current SW switching state are written and held as a corresponding SW value in the temporary holding area on the memory 102 (step S1703). Then, the CPU 101 returns to step S1702 until switching of all the switches SW in one SW group is completed (step S1704: No), and sequentially switches the SW setting one by one and continues the process of step S1703. And do it.

  When the switching of all the switches SW in one SW group is completed (step S1704: Yes), the CPU 101 reads out the best value RSRP and RSRQ in the SW group from the memory 102 (step S1705). Then, the CPU 101 changes each SW setting of the SW group so as to obtain the best value RSRP and the SW setting from which RSRQ is obtained (step S1706), and ends the above processing.

  In this fine tuning, fine adjustment is performed for the SW group in which there is a difference between the initial characteristics of the SW table 111 and the adjusted SW logic. In this fine tuning, the SW setting is finely adjusted without changing the setting value (initial value) of the SW table 111. As a specific example, for example, an example in which a difference appears in the SW group 1 will be described. The SW group 1 has three SWs SW1, SW2, and SW3, and the CPU 101 performs fine tuning in the following procedure.

(1a) SW1, SW2, and SW3 are set to “0, 0, 0” (step S1702).
(2a) The RSRP and RSRQ values obtained by the SW setting are temporarily stored in the memory 102 (step S1703).
(1b) The settings of SW1, SW2, and SW3 are changed to “0, 0, 1” (step S1702).
(2b) The values of RSRP and RSRQ obtained by the SW setting are temporarily stored in the memory 102 (step S1703).
(1c) Increase the setting of SW1, SW2, and SW3 one by one and repeat until the setting of “1, 1, 1” (step S1702), (2c) RSRP and RSRQ values obtained by each SW setting are stored in the memory 102, respectively. (Step S1703).
(3) The SW setting corresponding to the best RSRP and RSRQ values stored in the memory 102 is read (step S1704).
(4) The SW setting of each SW (SW1, SW2, SW3) of the SW group is changed so as to become the read SW setting (step S1705). This completes the fine tuning.

(Grounding structure example of grounding switch SW)
18 to 20 are diagrams illustrating an example of a GND grounding structure of the ground switching SW of the reception sensitivity control apparatus according to the embodiment. In the example shown in FIG. 18, a switch (SW) is used for GND grounding. The SW input (INPUT) is a terminal connected to the metal casing 105. The CPU 101 switches between opening and closing of the SW using the control terminal VCNT, and switches the metal housing 105 to GND ground or open.

  In the example shown in FIG. 19, the SPDT switch 1901 is used for GND grounding. The CPU 101 switches the output of OUT1 and OUT2 using the control terminal VCNT of the SPDT switch 1901. The OUT1 terminal is OPEN, and OUT2 is grounded to GND, which switches between opening of the metal housing 105 or GND grounding.

  In the example shown in FIG. 20, the SP3T switch 2001 is used for GND grounding. The SP3T switch 2001 selects any one of countermeasure circuits (trap circuits) 2002 for unnecessary resonance to the antenna in addition to OPEN and ground. The trap circuit is a circuit made of L, C, and the like that generates a predetermined impedance. Since the output of the SP3T switch 2001 has three terminals, the CPU 101 performs switch control by setting VCNT as a control signal to a 2-bit configuration (VCNT1, VCNT2).

  According to the embodiment described above, when the portable terminal is held by hand, the reception sensitivity can be improved regardless of how it is held in response to changes in reception sensitivity depending on how it is held. In addition, the reception sensitivity can be easily improved by using the functions of existing portable devices without using special parts such as new sensors and tuning device parts.

  In the embodiment, a metal case is provided in a part of the case, for example, at a place where the user's hand touches, and the place where the metal case is touched differs depending on how the mobile terminal is held. It is prepared in. Then, when unnecessary resonance due to the metal casing occurs in the use frequency band of communication by holding the casing, among the plurality of GND contacts provided in the metal casing, the GND grounding location is switched. Thereby, the unnecessary resonance frequency of the metal casing can be moved out of the communication frequency band, and the reception sensitivity can be improved.

  In order to adjust the reception sensitivity, a SW table in which a plurality of holding methods assumed by the portable terminal and the open / closed states of a plurality of GND contacts are combined in advance before the portable terminal is actually used. As a result, in actual use, the process for adjusting the reception sensitivity can be performed easily and easily. In the SW table, the open / closed state of the SW in which the reception characteristics (for example, RSRP, RSRQ, etc.) detected in each holding manner are good is set.

  The mobile terminal can detect the orientation and tilt of the mobile terminal with a built-in 6-axis sensor, etc., and by setting a combination assuming the way of holding with one hand or both hands according to the orientation of the mobile terminal in the SW table, It becomes possible to support various ways of holding mobile terminals. In addition, the process for adjusting the reception sensitivity during actual use can be performed in a short time.

  When the mobile terminal is actually used, a switch for grounding the GND is selected according to the setting (initial value) of the SW table. Perform tuning operation. The tuning result is used when the tuning result is improved from the initial value. As a result, not only the SW table setting but also the actual receiving state can be adjusted to the optimum reception sensitivity.

  By the way, in the embodiment, the setting examples are shown in FIGS. 11A to 11C as how to hold the mobile terminal. However, another way of holding the mobile terminal, for example, holding both hands with the mobile terminal upright, is further switched. You may add to the table. This makes it possible to prepare SW tables corresponding to various holding methods.

  Note that the method of receiving sensitivity control described in the present embodiment can be realized by executing a control program prepared in advance by a computer (CPU or the like) such as a target device (the portable terminal). This control program is recorded on a computer-readable recording medium such as a magnetic disk, an optical disk, or a USB (Universal Serial Bus) flash memory, and is executed by being read from the recording medium by the computer. The control program may be distributed via a network such as the Internet.

  The following additional notes are disclosed with respect to the embodiment described above.

(Appendix 1) A GND contact for grounding a metal casing provided in a casing of a mobile terminal at a plurality of different locations;
Corresponding to each holding method when the case is held by hand, a control unit that switches and controls a switch provided at the GND contact;
A reception sensitivity control apparatus comprising:

(Additional remark 2) The inclination detection part which detects the some direction of the said housing | casing,
A SW table in which switching states of a plurality of switches of the plurality of GND contacts having good reception characteristics for each of a plurality of directions of the casing corresponding to each holding method when the casing is held by hand,
The controller is
2. The reception sensitivity control apparatus according to appendix 1, wherein, when the mobile terminal is actually used, the GND contact corresponding to the detected orientation of the casing is grounded with reference to the SW table.

(Supplementary Note 3) The SW table includes a plurality of group settings in which a plurality of GND contacts adjacent to each other are divided into one group,
The controller is
If the detected reception characteristics change beyond a predetermined range during actual use of the mobile terminal, the SW table is referred to, the group setting of the detected orientation of the casing is read, and the group setting 3. The reception sensitivity control apparatus according to claim 2, wherein tuning is performed such that the plurality of GND contact switches are sequentially switched and grounded, and the GND contact is grounded in a switching state of a switch having good reception characteristics.

(Appendix 4) The control unit
The reception sensitivity control apparatus according to appendix 3, wherein the GND contact is grounded by the tuning when the reception characteristic after the tuning is performed is better than the reception characteristic based on the setting of the SW table.

(Supplementary Note 5) The control unit
5. The reception sensitivity control apparatus according to any one of appendices 1 to 4, wherein RSRP (Reference Signal Received Power) and RSRQ (Reference Signal Received Quality) are used as the reception characteristics.

(Supplementary Note 6) The SW table includes a plurality of orientations for each holding method of the case when the case is held by hand. Any one of Supplementary notes 2 to 5, wherein each of the holding by one hand when vertically held and the vertical direction of the casing when holding the case horizontally by both hands is set. The receiving sensitivity control device described in 1.

(Appendix 7) A reception sensitivity control method for a mobile terminal having a GND contact for grounding a metal casing provided in a casing at a plurality of different locations,
Corresponding to each holding method when the case is held by hand, the switch provided at the GND contact is switched and controlled.
And a reception sensitivity control method.

(Supplementary note 8) Before actual use of the mobile terminal, switching of the plurality of GND contact switches having good reception characteristics for each of the plurality of orientations of the casing corresponding to each way of holding the casing. Set the state in the SW table,
The reception sensitivity control method according to appendix 7, characterized by:

(Supplementary note 9) The reception sensitivity control method according to supplementary note 8, wherein the GND contact corresponding to the detected orientation of the casing is grounded with reference to the SW table when the mobile terminal is actually used.

(Appendix 10) A reception sensitivity control program for a mobile terminal,
In the computer of the portable terminal,
Corresponding to each holding method of the portable terminal case, the switch provided on the GND contact for grounding the metal case provided at the case at a plurality of different locations is controlled.
A reception sensitivity control program for executing processing.

100 Reception Sensitivity Control Device 101 CPU
DESCRIPTION OF SYMBOLS 102 Memory 103 Inclination detection part 105 Metal housing 111 SW table 112 6 axis | shaft sensor 200 Portable terminal 201 Case 202 Display part 203 Antenna 301 (301a, 301b) Circuit board 302 Battery 303 (303a-303j) GND contact point 1401 Level range setting table

Claims (9)

A GND contact for grounding a metal casing provided in the casing of the mobile terminal at a plurality of different locations;
Corresponding to each holding method when the case is held by hand, a control unit that switches and controls a switch provided at the GND contact;
A reception sensitivity control apparatus comprising: An inclination detector for detecting a plurality of directions of the housing;
A SW table in which switching states of a plurality of switches of the plurality of GND contacts having good reception characteristics for each of a plurality of directions of the casing corresponding to each holding method when the casing is held by hand,
The controller is
The reception sensitivity control apparatus according to claim 1, wherein the GND contact corresponding to the detected orientation of the casing is grounded by referring to the SW table when the mobile terminal is actually used. The SW table includes a plurality of group settings obtained by dividing a plurality of the GND contacts adjacent to each other into one group,
The controller is
If the detected reception characteristics change beyond a predetermined range during actual use of the mobile terminal, the SW table is referred to, the group setting of the detected orientation of the casing is read, and the group setting 3. The reception sensitivity control apparatus according to claim 2, wherein a plurality of the GND contact switches are sequentially switched and grounded, and tuning is performed to ground the GND contact in a switching state of a switch having good reception characteristics. The controller is
4. The reception sensitivity control apparatus according to claim 3, wherein when the reception characteristic after the tuning is performed is better than the reception characteristic based on the setting of the SW table, the GND contact is grounded by the tuning. The controller is
The reception sensitivity control apparatus according to any one of claims 1 to 4, wherein RSRP (Reference Signal Received Power) and RSRQ (Reference Signal Received Quality) are used as the reception characteristics.   The SW table has a plurality of orientations for each holding method when the case is held by hand, and the case is held vertically by holding the case by one hand when the case is held vertically. 6. The method according to any one of claims 2 to 5, wherein each of a holding by one hand at the time and a vertical direction of the housing when the housing is held with both hands is set. Receiver sensitivity control device. A reception sensitivity control method for a mobile terminal having a GND contact for grounding a metal casing provided in a casing at a plurality of different locations,
Corresponding to each holding method when the case is held by hand, the switch provided at the GND contact is switched and controlled.
And a reception sensitivity control method. Before actual use of the portable terminal, the SW table indicates the switching state of the plurality of GND contact switches having good reception characteristics for each of the plurality of orientations of the casing corresponding to each way of holding the casing. Set to
The reception sensitivity control method according to claim 7. A reception sensitivity control program for a mobile terminal,
In the computer of the portable terminal,
Corresponding to each holding method of the portable terminal case, the switch provided on the GND contact for grounding the metal case provided at the case at a plurality of different locations is controlled.
A reception sensitivity control program for executing processing.

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