TWI753540B - communication device - Google Patents

Abstract

Embodiments provide a semiconductor memory device capable of expanding the communication range.

A semiconductor memory device according to an embodiment includes a first loop antenna, a second loop antenna, and a controller. The said 1st loop antenna produces|generates a 2nd magnetic field based on the electromagnetic induction by a 1st magnetic field. The second loop antenna generates an induced electromotive force based on electromagnetic induction by the second magnetic field. The controller is operable based on the induced electromotive force generated in the second loop antenna, and communicates with a first external device that generates the first magnetic field through the second loop antenna.

Description

communication device

Embodiments of the present invention relate to semiconductor memory devices.

[Related Application]

This application enjoys priority based on Japanese Patent Application No. 2018-105255 (filing date: May 31, 2018) and Japanese Patent Application No. 2018-208406 (filing date: November 5, 2018). This application contains all the contents of the basic application by reference to these basic applications.

A device is known that includes a loop antenna and performs wireless communication with an external device by utilizing electromagnetic induction generated by the loop antenna based on a magnetic field generated by an external device.

Because of the configuration of the loop antenna of the external device, it is difficult for the magnetic field lines to pass through the inside of the loop antenna, and wireless communication may become difficult.

Embodiments provide a semiconductor memory device capable of expanding the communication range.

A semiconductor memory device according to an embodiment includes a first loop antenna, a second loop antenna, and a controller. The aforementioned first loop antenna is constructed based on the first magnetic field The resulting electromagnetic induction generates a second magnetic field. The second loop antenna generates an induced electromotive force based on electromagnetic induction by the second magnetic field. The controller is operable based on the induced electromotive force generated in the second loop antenna, and communicates with a first external device that generates the first magnetic field through the second loop antenna.

(First Embodiment) Hereinafter, a first embodiment will be described with reference to FIGS. 1 to 4 . In addition, in this specification, regarding the description of the component of an embodiment, and this element, there are cases where plural expressions are described. Elements and descriptions with plural representations may be other representations not described. Furthermore, components and descriptions that are not represented in plural may be other representations not described. FIG. 1 is an exemplary plan view schematically showing a memory card 11 according to the first embodiment. The memory card 11 is an example of a semiconductor memory device. In this embodiment, the memory card 11 is a microSD card. In addition, the semiconductor memory device may be, for example, an SD card, a multimedia card, or other devices such as a USB flash memory. Semiconductor memory devices include devices or systems having semiconductor wafers. As shown in each figure, the X-axis, the Y-axis, and the Z-axis are defined in the specification. The X, Y, and Z axes are perpendicular to each other. The X axis is drawn along the width of the memory card 11 . The Y axis is drawn along the length of the memory card 11 . The Z axis is drawn along the thickness of the memory card 11 . The memory card 11 of this embodiment is adapted to the wireless communication technology. For example, Near Field Communication (NFC) using a frequency of 13.56 MHz is applicable to the memory card 11 . Other wireless communication technologies may also be applied to the memory card 11 . The NFC-compatible memory card 11 uses electromagnetic induction to induce current with a wireless antenna. Therefore, as described below, the memory card 11 has, for example, a wireless antenna formed in a shape that can be called a coil shape, a spiral shape, or a spiral shape. FIG. 2 is an exemplary block diagram schematically showing an example of the configuration of a system including the memory card 11 of the first embodiment. As shown in FIG. 2 , the memory card 11 is electrically connected to the host device 12 . The host device 12 is an example of a second external device. Next, the memory card 11 performs wireless communication with the wireless communication host device 13 . The wireless communication host device 13 is an example of the first external device. The host device 12 and the wireless communication host device 13 are, for example, a personal computer, a portable computer, a smart phone, a mobile phone, a server, a smart card, a reader/writer, or other devices, respectively. The memory card 11 includes a plurality of interface (I/F) terminals 22 , a wireless antenna 23 , a controller 24 , and a flash memory 25 . The I/F terminal 22 is an example of a terminal. The wireless antenna 23 is an example of a second loop antenna, and may be called a coil or a secondary coil, for example. The controller 24 includes: a wireless communication controller 26 , a memory controller 27 , and a bridge controller 28 . In this embodiment, the wireless communication controller 26, the memory controller 27, and the bridge controller 28 are separate electronic components. However, the wireless communication controller 26, the memory controller 27, and the bridge controller 28 may be included in the controller 24 as one electronic component. Also, for example, a plurality of electronic components, wirings, and programs may constitute each of the wireless communication controller 26 , the memory controller 27 , and the bridge controller 28 . That is, the wireless communication controller 26, the memory controller 27, and the bridge controller 28 may be constituted by a single electronic element, a plurality of electronic elements, or one or a plurality of electronic elements and a program, respectively. The wireless communication controller 26 controls communication between the memory card 11 and the wireless communication host device 13 . The wireless communication controller 26 has a memory unit 26a. The memory controller 27 controls data writing and reading to and from the flash memory 25 . The bridge controller 28 controls the wireless communication controller 26 and the memory controller 27 . Next, the bridge controller 28 controls the communication between the memory card 11 and the host device 12 . If the memory card 11 is electrically connected to the host device 12 , the memory card 11 operates by the power supplied from the host device 12 . For example, data is written to the memory card 11 by the host device 12 , or data is read by the host device 12 . The memory card 11 can transmit and receive data with the wireless communication host device 13 in a state where it is not connected to another device such as the host device 12 and is not supplied with power from the other device. For example, the memory card 11 causes the wireless antenna 23 to generate an induced electromotive force based on electromagnetic induction, thereby enabling data transmission and reception with the wireless communication host device 13 . The memory card 11 performs communication based on the NFC standard, for example, at a frequency of about 13.56 MHz, and transmits and receives data with the wireless communication host device 13 . In this way, the memory card 11 can operate without being supplied with power from the host device 12 . The memory card 11 of the present embodiment performs data transmission and reception with the host device 12 according to the SD interface. The memory card 11 may also use other interfaces to send and receive data with the host device 12 . The memory card 11 transmits and receives data with the wireless communication host device 13 along the NFC interface. The memory card 11 may also use other wireless communication interfaces to send and receive data with the wireless communication host device 13 . In addition, the host device 12 and the wireless communication host device 13 may be the same device. FIG. 3 is a schematic cross-sectional view of the memory card 11 of the first embodiment taken along the line F3-F3 in FIG. 1 . As shown in FIG. 3 , the memory card 11 further includes: a substrate 31 , a middle antenna 32 , and a protective shell 33 . The intermediate antenna 32 is an example of a first loop antenna, and may be called a coil or a booster coil, for example. The substrate 31 is, for example, a printed circuit board (PCB). In the present embodiment, the substrate 31 has, for example, a plurality of layers. In addition, the substrate 31 is not limited to this example. The substrate 31 has a first surface 31a and a second surface 31b. The first surface 31a is a substantially flat surface in the negative direction of the Z axis (the direction opposite to the arrow of the Z axis). The second surface 31b is located on the opposite side of the first surface 31a, and is a substantially flat surface in the positive direction of the Z-axis (direction indicated by the arrow of the Z-axis). As shown in FIG. 1 , the memory card 11 and the substrate 31 are each formed in a substantially rectangular shape extending in the Y-axis direction. The substrate 31 further includes a first edge 31c, a second edge 31d, a third edge 31e, and a fourth edge 31f. The first edge 31c and the second edge 31d each extend in the X-axis direction. The first edge 31c is spaced apart from the second edge 31d in the positive direction of the Y-axis (direction indicated by the arrow of the Y-axis). The third edge 31e extends in the Y-axis direction. The fourth edge 31f extends substantially in the Y-axis direction. The fourth edge 31f forms a depression or protrusion. The first edge 31c and the second edge 31d are shorter than the third edge 31e and the fourth edge 31f, respectively. Therefore, the first edge 31c and the second edge 31d form the short sides of the substantially rectangular substrate 31 . The third edge 31e and the fourth edge 31f form the long sides of the substantially rectangular substrate 31 . A plurality of I/F terminals 22 and an intermediate antenna 32 are provided on the substrate 31 . The plurality of I/F terminals 22 are provided on the first surface 31a, are adjacent to the first edge 31c, and are arranged along the first edge 31c. The I/F terminal 22 of the present embodiment is an SD interface terminal, and ensures electrical connection to the host device 12 . In other words, the I/F terminal 22 can be electrically connected to the host device 12 . The wireless antenna 23 , the controller 24 , and the flash memory 25 are mounted on the substrate 31 . The flash memory 25 is arranged on the second surface 31b. The wireless communication controller 26, the memory controller 27, and the bridge controller 28 are disposed on the flash memory 25, and are electrically connected to the pads of the second surface 31b, for example, by wire bonding. In addition, the implementation of the wireless communication controller 26, the memory controller 27, and the bridge controller 28 is not limited to this example. The protective case 33 is, for example, a so-called mold resin made of synthetic resin, which is a non-magnetic material and an insulator. The protective case 33 may also be made of other materials. The protective case 33 covers the first surface 31 a and the second surface 31 b of the substrate 31 , the wireless antenna 23 , the controller 24 , and the external flash memory 25 , and forms the outer surface of the memory card 11 . As shown in FIG. 3 , like the memory card 11 and the substrate 31 , the protective case 33 is also formed in a substantially rectangular shape extending in the Y-axis direction. The protective case 33 has a first outer surface 33a, a second outer surface 33b, a first edge 33c, and a second edge 33d. The first outer surface 33a is an example of the outer surface. The first outer surface 33 a and the second outer surface 33 b are exposed to the outside of the memory card 11 , respectively, and are part of the outer surface of the memory card 11 . The first outer surface 33a is a substantially flat surface in the negative direction of the Z-axis. The second outer surface 33b is located on the opposite side of the first outer surface 33a, and is a substantially flat surface in the positive direction of the Z-axis. The first edge 33c and the second edge 33d form the short sides of the substantially rectangular protective case 33 and extend in the X-axis direction. The first edge 33c is spaced in the positive direction of the Y-axis with respect to the second edge 33d. The first edge 33c and the second edge 33d of the protective case 33 overlap with the first edge 31c and the second edge 31d of the substrate 31 . In addition, the 1st edge 33c and the 2nd edge 33d are not limited to this example. The plurality of I/F terminals 22 are not covered by the protective case 33 and are exposed on the first outer surface 33a. The plurality of I/F terminals 22 are adjacent to the first edge 33c of the protective case 33, and are arranged along the first edge 33c. Further, on the second outer surface 33b, an image showing, for example, the capacity of the memory card 11 is printed. In the present embodiment, the wireless antenna 23 is a loop antenna having a coil wound in a spiral shape and extending in the X-axis direction. The wireless antenna 23 is wound around the magnetic body 41 . The magnetic body 41 is formed in a substantially rectangular parallelepiped shape extending in the X-axis direction. In addition, the magnetic body 41 may be formed in other shapes such as a cylindrical shape. In addition, the magnetic body 41 may be omitted. The center Ax1 of the helical wireless antenna 23 extends in the X-axis direction. The length of the wireless antenna 23 in the X-axis direction is longer than the length of the wireless antenna 23 in the Y-axis direction, and is also longer than the length of the wireless antenna 23 in the Z-axis direction. In addition, the size of the wireless antenna 23 is not limited to this example. In addition, the direction in which the center Ax1 of the wireless antenna 23 extends may be locally changed. The wireless antenna 23 is a so-called chip antenna, and is mounted on the second surface 31 b of the substrate 31 by surface mounting. As shown in FIG. 1 , the wireless antenna 23 is adjacent to the second edge 31d of the substrate 31 and the second edge 33d of the protective case 33, and extends along the second edges 31d and 33d. Therefore, the wireless antenna 23 is spaced apart from the plurality of I/F terminals 22 in the negative direction of the Y-axis (the direction opposite to the arrow of the Y-axis). As shown in FIG. 2 , the wireless antenna 23 is electrically connected to the wireless communication controller 26 . The wireless antenna 23 supplies the induced electromotive force to the wireless communication controller 26 based on the electromagnetic induction caused by the magnetic field lines passing through the inside of the wireless antenna 23 . Thereby, the wireless antenna 23 communicates with an external device based on electromagnetic induction. As shown in FIG. 1 , in the present embodiment, the intermediate antenna 32 is formed by the conductor pattern 45 provided on one layer of the substrate 31 . The conductor pattern 45 is made of a conductor such as copper, and on the substrate 31 , for example, pads, wirings, holes, and ground plates are formed. In addition, the intermediate antenna 32 may be made of other materials such as lead wires. The intermediate antenna 32 is a loop antenna formed by a spiral-shaped conductor pattern 45 . The intermediate antenna 32 is formed in a substantially quadrangular loop. In addition, other forms such that the intermediate antenna 32 is formed in a circular shape may be used. As shown in FIG. 3 , the intermediate antenna 32 is provided in the middle layer of the substrate 31, and is located between the first surface 31a and the second surface 31b. Therefore, the intermediate antenna 32 is located between the wireless antenna 23 and the first outer surface 33a. The intermediate antenna 32 is separated from the wireless antenna 23 via, for example, an insulating layer of the substrate 31 . As shown in FIG. 1 , the intermediate antenna 32 is adjacent to the second edge 31d and the third edge 31e. A part of the intermediate antenna 32 overlaps with a part of the wireless antenna 23 in the Z-axis direction. In addition, the positions of the intermediate antenna 32 and the wireless antenna 23 are not limited to this example. The center Ax2 of the spiral-shaped intermediate antenna 32 extends in the Z-axis direction. Therefore, the direction in which the center Ax1 of the wireless antenna 23 extends (X-axis direction) intersects the direction in which the center Ax2 of the intermediate antenna 32 extends (Z-axis direction). The direction in which the center Ax1 of the wireless antenna 23 extends and the direction in which the center Ax2 of the intermediate antenna 32 extends are vertical in this embodiment, but may intersect at an angle smaller than 90°. The cross section of the inner side of the intermediate antenna 32 perpendicular to the direction in which the center Ax2 extends (Z-axis direction) is larger than the cross-section of the inner side of the wireless antenna 23 perpendicular to the direction in which the center Ax1 extends (X-axis direction). In other words, the cross section inside the intermediate antenna 32 in the X-Y plane is larger than the cross section inside the radio antenna 23 in the Y-Z plane. The cross section of the inner side of the intermediate antenna 32 is an area surrounded by the spiral conductor pattern 45 . The cross section of the inner side of the wireless antenna 23 is an area surrounded by the helical wireless antenna 23 . As in FIG. 1 , the wireless antenna 23 and the intermediate antenna 32 intersect with each other in a plan view viewed in the Z-axis direction. In addition, in a plan view viewed in the Z-axis direction, one end portion 23 a of the wireless antenna 23 in the X-axis direction is positioned inside the outer edge 32 a of the intermediate antenna 32 . The end portion 23a is an example of the first end portion. The outer edge 32a is formed by the outermost wire of the wireless antenna 23 wound in a spiral shape. The other end 23 a of the radio antenna 23 in the X-axis direction is located outside the outer edge 32 a of the intermediate antenna 32 . The end portion 23b is an example of the second end portion, and is located on the opposite side of the end portion 23a. In addition, both end portions 23 a and 23 b of the wireless antenna 23 may be located outside the outer edge 32 a of the intermediate antenna 32 . One end portion 23a of the wireless antenna 23 is closer to the third edge 31e than the fourth edge 31f of the substrate 31 . The other end 23b of the wireless antenna 23 is closer to the fourth edge 31f than the third edge 31e. In the X-axis direction, the distance between the one end portion 23a and the third edge 31e of the wireless antenna 23 is longer than the distance between the other end portion 23b and the fourth edge 31f. As shown in FIG. 2 , the intermediate antenna 32 is electrically separated from the circuit C1 including the I/F terminal 22 , the wireless antenna 23 , the controller 24 , and the flash memory 25 . In other words, the middle antenna 32 is electrically independent from the wireless antenna 23 . The terminal of the intermediate antenna 32 is connected to the capacitor 49 . Thereby, the intermediate antenna 32 forms a resonance circuit C2 independent from the circuit C1. In addition, the intermediate antenna 32 is not limited to this example. For example, the intermediate antenna 32 or the conductor pattern 45 connected to the intermediate antenna 32 may be formed on a plurality of layers of the substrate 31 to form a capacitor between the conductor patterns 45 of the plurality of layers. Not limited to the capacitor 49 , a capacitor formed by such a conductor pattern 45 , or other capacitors may form the resonance circuit C2 together with the intermediate antenna 32 . By passing magnetic lines of force through the interior of the intermediate antenna 32 , electromagnetic induction is generated in the intermediate antenna 32 , and current flows through the intermediate antenna 32 . By allowing current to flow in the intermediate antenna 32 , the intermediate antenna 32 generates magnetic field lines passing through the interior of the intermediate antenna 32 . In the memory card 11 of the present embodiment to which NFC is applied, the resonance frequency of the intermediate antenna 32 is set to 10 MHz or more and 20 MHz or less. For example, the resonance frequency of the intermediate antenna 32 is set to about 13.56 MHz. The resonant frequency of the intermediate antenna 32 is adjusted, for example, by the capacitor 49 . In the memory card 11 described above, the wireless antenna 23 of FIG. 2 generates current or voltage based on electromagnetic induction after receiving the radio wave transmitted from the wireless communication host device 13 . The wireless antenna 23 supplies the generated power to the wireless communication controller 26 . The wireless antenna 23 of the present embodiment is set to correspond to a predetermined frequency or frequency band corresponding to NFC. For example, the resonance frequency of the wireless antenna 23 is set to about 13.56 MHz. The wireless antenna 23 sends the data received from the wireless communication host device 13 to the wireless communication controller 26 . Then, the wireless antenna 23 sends the data received from the wireless communication controller 26 to the wireless communication host device 13 . The wireless communication controller 26 can communicate with the wireless communication host device 13 through the wireless antenna 23 . The wireless communication controller 26 controls the use of NFC with respect to the wireless antenna 23 of the wireless communication host device 13 . The wireless communication controller 26 can be operated by the electric power generated in the wireless antenna 23 based on the above-mentioned electromagnetic induction. The wireless communication controller 26 receives a signal or data represented by a current or voltage generated in the wireless antenna 23 based on the radio waves from the wireless communication host device 13, and operates in response to the signal or data. For example, during operation, the wireless communication controller 26 receives data from the wireless communication host device 13 through the wireless antenna 23 at a predetermined frequency corresponding to NFC, and writes the data into the memory portion 26a. When the wireless communication controller 26 operates, the data written in the memory unit 26 a is read out, and the data is sent to the wireless communication host device 13 through the wireless antenna 23 . More specifically, after the wireless communication controller 26 receives a signal corresponding to a predetermined frequency of NFC through the wireless antenna 23, it can perform NFC communication. The bridge controller 28 can communicate with the host device 12 through the I/F terminal 22 . When writing to the flash memory 25 , the bridge controller 28 sends the data received from the host device 12 through the I/F terminal 22 to the memory controller 27 . When reading to the flash memory 25 , the bridge controller 28 sends the data received from the memory controller 27 to the host device 12 through the I/F terminal 22 . For example, when the memory card 11 is electrically connected to the host device 12, sufficient power is supplied to the wireless communication controller 26. At this time, the wireless communication controller 26 may write the data received from the wireless communication host device 13 through the wireless antenna 23 through NFC to the flash memory 25 through the bridge controller 28 and the memory controller 27 . When sufficient power is supplied to the wireless communication controller 26, the wireless communication controller 26 will read the data written in the flash memory 25 through the bridge controller 28 and the memory controller 27, generate data, and write the data in The memory unit 26a may also be used. When sufficient power is supplied to the wireless communication controller 26, the wireless communication controller 26 will read part or all of the data written in the flash memory 25 through the bridge controller 28 and the memory controller 27, The data may also be sent to the wireless communication host device 13 through the wireless antenna 23 . The memory portion 26a is a low-power consumption memory that can be operated by the electric power generated in the wireless antenna 23 . The power consumption for writing and reading data in the memory unit 26 a is lower than the power consumption for writing and reading data in the flash memory 25 . The memory unit 26a is, for example, a nonvolatile memory. The storage unit 26 a stores data based on the control of the wireless communication controller 26 . In addition, the memory part 26a may be a memory that temporarily stores data. The memory part 26a is, for example, an EEPROM (Electrically Erasable Programmable Read-Only Memory). The memory unit 26a may be another memory. As described above, the wireless communication controller 26 and the memory unit 26 a can be operated by the electric power induced by the wireless antenna 23 by the radio waves from the wireless communication host device 13 . However, the wireless communication controller 26 and the memory unit 26a may operate by the power supplied from the host device 12 when the memory card 11 is supplied with power from the host device 12 . The flash memory 25 is, for example, a NAND-type flash memory. In addition, the memory card 11, instead of the flash memory 25, has a NOR type flash memory, a magnetoresistive random access memory (MRAM), a phase change memory (PRAM), and a resistance change memory. Other non-volatile memories such as Resistive Random Access Memory (ReRAM) or Ferroelectric Random Access Memory (FeRAM) may also be used. The memory controller 27 controls data writing and reading to and from the flash memory 25 . More specifically, when the memory controller 27 receives a write command and data from the host device 12 through the I/F terminal 22 and the bridge controller 28 , the data is written into the flash memory 25 . When the memory controller 27 receives a read command from the host device 12 through the I/F terminal 22 and the bridge controller 28, it reads out data from the flash memory 25, and passes the data through the bridge controller 28 and the I/F. The terminal 22 is sent to the host device 12 . For example, when the memory card 11 is electrically connected to the host device 12, sufficient power is supplied to the memory controller 27. At this time, the memory controller 27 may write the data received from the wireless communication host device 13 through the wireless antenna 23 , the wireless communication controller 26 , and the bridge controller 28 to the flash memory 25 . When sufficient power is supplied to the memory controller 27, the data read from the flash memory 25 by the memory controller 27 is sent to the wireless communication host through the bridge controller 28, the wireless communication controller 26, and the wireless antenna 23. The device 13 can also send. The flash memory 25 and the memory controller 27 are operated by power supplied from the host device 12 . The above-mentioned data, for example, may be data transmitted and received between the wireless communication host device 13 and the memory card 11 according to the NFC interface, characteristic data of data written in the flash memory 25 may also be obtained from the wireless communication host device 13 The characteristic data received by the wireless communication controller 26 through the wireless antenna 23 may be the characteristic data of the flash memory 25 or the characteristic data of the memory card 11 . More specifically, the data are, for example, data of a part (eg, the first or the last) of the image data written in the flash memory 25 , thumbnail data, management information of the data written in the flash memory 25 , The memory capacity of the flash memory 25, the remaining capacity of the flash memory 25, the name of the file written to the flash memory 25, the generation time of the data, the recording time data when the data is image data, the flash memory The number of files in the memory 25 is also acceptable. In the present embodiment, the write instruction and data from the host device 12 are first received by the bridge controller 28 and then received by the memory controller 27 . This is because, first, the bridge controller 28 determines whether the write instruction and data are received from the host device 12 or from the wireless communication host device 13, and the operation is switched as a result of the determination. In the present embodiment, for example, the memory card 11 and the wireless communication host device 13 transmit and receive data regarding permission or prohibition of writing and reading data to and from the flash memory 25 (hereinafter, referred to as “lock function data”). . The memory unit 26a stores the data of the lock function. In addition, the memory card 11 and the memory unit 26a are not limited to this example. Based on the data received from the wireless communication host device 13, the wireless communication controller 26 writes the data of the lock function into the memory unit 26a. When the bridge controller 28 receives the data from the host device 12, it refers to the data of the lock function stored in the memory unit 26a. The bridge controller 28 does not perform data transmission and reception with the memory controller 27 when the writing and reading of data in the flash memory 25 are prohibited. The bridge controller 28 does not perform data transmission and reception with the memory controller 27 when the writing and reading of data in the flash memory 25 are prohibited. Hereinafter, the electromagnetic induction of the wireless antenna 23 will be described in detail. FIG. 4 is an exemplary perspective view schematically showing the memory card 11 and the wireless communication host device 13 according to the first embodiment. As shown in FIG. 4, the wireless communication host device 13 has an antenna 13a. The antenna 13a, for example, can also be referred to as a primary coil. The antenna 13a is, for example, a spiral-shaped loop antenna. The antenna 13a is formed in a substantially square ring shape. In addition, the antenna 13a may be formed in another shape in a circular shape. The inner section of the antenna 13a is larger than the inner section of the intermediate antenna 32 . In addition, the size of the antenna 13a is not limited to this example. The antenna 13a generates, for example, a first magnetic field M1 having a frequency of about 13.56 MHz by transmitting radio waves. In addition, the antenna 13a of the wireless communication host device 13 may generate only the first magnetic field M1. 4 and 3 schematically show the lines of force of the first magnetic field M1 by arrows. Normally, the magnetic field lines of the first magnetic field M1 pass through the inside of the antenna 13a and expand in a slightly radial shape from the antenna 13a. During wireless communication with the wireless communication host device 13, the memory card 11 is disposed above the antenna 13a so that the direction in which the center of the antenna 13a extends and the direction in which the center Ax2 of the intermediate antenna 32 extends are substantially parallel. For example, the memory card 11 is arranged at the first position P1 or the second position P2 in FIG. 4 with respect to the antenna 13a. The wireless antenna 23 of the memory card 11 at the first position P1 intersects with the antenna 13a when viewed in plan from the Z-axis direction. At this time, the magnetic field lines of the first magnetic field M1 can pass through the inside of the wireless antenna 23 . The wireless antenna 23 generates an induced electromotive force based on electromagnetic induction caused by the magnetic field lines of the first magnetic field M1 passing through the inside of the wireless antenna 23 . The wireless communication controller 26 operates based on the induced electromotive force generated in the wireless antenna 23 , and communicates with the wireless communication host device 13 via the wireless antenna 23 . On the other hand, when viewed in plan from the Z-axis direction, the wireless antenna 23 of the memory card 11 at the second position P2 extends parallel to the antenna 13a. At this time, the center Ax1 of the wireless antenna 23 is perpendicular to the magnetic field lines of the first magnetic field M1 , and it is difficult for the magnetic field lines of the first magnetic field M1 to pass through the inside of the wireless antenna 23 . Even if electromagnetic induction is generated in the wireless antenna 23 by the magnetic field lines of the first magnetic field M1 , the induced electromotive force may not be sufficient for the operation of the wireless communication controller 26 . The wireless antenna 23 is longly curled in the X-axis direction. Therefore, the directivity of the wireless antenna 23 is stronger than that of the intermediate antenna 32, for example, and it is difficult for the magnetic field lines of the first magnetic field M1 to pass through the inside. In addition, the area of the wireless antenna 23 on the substrate 31 is small. As shown in FIG. 3 , the magnetic field lines of the first magnetic field M1 can pass through the inside of the intermediate antenna 32 . Furthermore, the intermediate antenna 32 can concentrate the magnetic field lines of the first magnetic field M1 by resonance. Electromagnetic induction is generated in the intermediate antenna 32 by the magnetic field lines passing through the first magnetic field M1 inside the intermediate antenna 32 . When a current flows through the intermediate antenna 32 based on electromagnetic induction, the intermediate antenna 32 generates the second magnetic field M2. FIG. 3 schematically shows the lines of force of the second magnetic field M2 by arrows. The magnetic field lines of the second magnetic field M2 pass through the inside of the intermediate antenna 32 and expand from the intermediate antenna 32 to a slightly radial shape. The radio antenna 23 and the intermediate antenna 32 cross each other when viewed in plan from the Z-axis direction. Therefore, the magnetic field lines of the second magnetic field M2 can pass through the inside of the wireless antenna 23 . The wireless antenna 23 generates an induced electromotive force based on electromagnetic induction caused by the magnetic field lines of the second magnetic field M2 passing through the inside of the wireless antenna 23 . That is, after the electromagnetic induction is generated in the intermediate antenna 32, the electromagnetic induction is generated in the wireless antenna 23 in a chain. The wireless communication controller 26 operates based on the induced electromotive force generated in the wireless antenna 23 , and communicates with the wireless communication host device 13 via the wireless antenna 23 . Furthermore, the magnetic field lines of the first magnetic field M1 pass through the interior of the intermediate antenna 32 due to resonance, and change directions so as to expand radially from the intermediate antenna 32 . The magnetic field lines of the first magnetic field M1 whose direction is changed can pass through the inside of the wireless antenna 23 . Therefore, the density of magnetic lines of force inside the wireless antenna 23 increases, and the induced electromotive force energy in the wireless antenna 23 increases. As described above, the wireless antenna 23 can directly transmit and receive radio waves and magnetic fields with the antenna 13 a of the wireless communication host device 13 , and can also receive power generation waves and magnetic fields with the antenna 13 a through the intermediate antenna 32 . That is, the memory card 11 can communicate with the wireless communication host device 13 not only at the position where electromagnetic induction is generated by the wireless antenna 23 but also at the position where electromagnetic induction is generated by the intermediate antenna 32 . For example, the memory card 11 may communicate with another wireless communication host device 13 in a state of being accommodated in the connector of the host device 12 . At this time, since the intermediate antenna 32 is covered by the host device 12 and the metal casing of the connector, it is difficult for the magnetic field lines of the first magnetic field M1 to pass through the interior of the intermediate antenna 32 . However, the wireless antenna 23 is located near the open end of the connector. Therefore, the magnetic field lines of the first magnetic field M1 can pass through the inside of the wireless antenna 23 , and the memory card 11 can communicate with the wireless communication host device 13 . For example, when the memory card 11 is electrically connected to the host device 12 and the wireless communication controller 26 is supplied with sufficient power, the wireless communication controller 26 may also function as a reader/writer. At this time, the wireless communication controller 26 supplies current or voltage representing the signal or data to the wireless antenna 23 . Thereby, the wireless antenna 23 generates the third magnetic field M3 by, for example, transmitting radio waves. The intermediate antenna 32 generates the second magnetic field M2 based on electromagnetic induction by the third magnetic field M3. After the second magnetic field M2 generates electromagnetic induction in the antenna 13a, the wireless communication host device 13 receives the signal or data represented by the current or voltage generated in the antenna 13a, and operates according to the signal or data. In the memory card 11 of the first embodiment described above, the intermediate antenna 32 generates the second magnetic field M2 based on electromagnetic induction by the first magnetic field M1. The wireless antenna 23 generates an induced electromotive force based on electromagnetic induction by the second magnetic field M2. The wireless communication controller 26 of the controller 24 operates based on the induced electromotive force generated in the wireless antenna 23 , and can communicate with the wireless communication host device 13 via the wireless antenna 23 . That is, the intermediate antenna 32 converts the first magnetic field M1 into the second magnetic field M2 suitable for the electromagnetic induction of the wireless antenna 23 . In the present embodiment, the intermediate antenna 32 performs conversion between the first magnetic field M1 and the second magnetic field M2 having different directions. Thereby, the communication range of the memory card 11 can be expanded compared with the case where the intermediate antenna 32 is absent. The second loop antenna can generate an induced electromotive force based on electromagnetic induction by the first magnetic field M1. That is, the wireless communication controller 26 generates the second magnetic field M2 when the magnetic field lines of the first magnetic field M1 directly pass through the inside of the wireless antenna 23 and the intermediate antenna 32 generates the second magnetic field M2 because the magnetic field lines of the first magnetic field M1 pass through the inside of the intermediate antenna 32. Communication with the wireless communication host device 13 can be performed in both cases when the magnetic field lines of the second magnetic field M2 pass through the inside of the wireless antenna 23 . Thereby, the communication range of the memory card 11 can be expanded compared with the case where the intermediate antenna 32 is absent. As in the first position P1, when the center Ax1 of the wireless antenna 23 extends in a direction parallel to the line of the antenna 13a, and the center Ax1 of the wireless antenna 23 extends in a direction perpendicular to the direction of the magnetic field lines of the first magnetic field M1, it is difficult for the magnetic field lines to pass through the wireless antenna 23 Inside, it is difficult to generate electromagnetic induction in the wireless antenna 23 . In the present embodiment, the direction in which the center Ax2 of the intermediate antenna 32 extends intersects the direction in which the center Ax1 of the wireless antenna 23 extends. Thereby, the magnetic field lines of the first magnetic field M1 can pass through at least one of the intermediate antenna 32 and the wireless antenna 23 , and electromagnetic induction can be generated in at least one of the intermediate antenna 32 and the wireless antenna 23 . Thereby, the controller 24 can communicate with the wireless communication host device 13 more reliably, and the communication range of the memory card 11 can be expanded. The one end portion 23 a of the wireless antenna 23 is located inside the outer edge 32 a of the intermediate antenna 32 in a plan view viewed in a direction in which the center Ax2 of the intermediate antenna 32 extends. Thereby, the magnetic field lines of the second magnetic field M2 inside the intermediate antenna 32 easily enter the wireless antenna 23 from the one end 23a of the wireless antenna 23 , and electromagnetic induction is easily generated in the wireless antenna 23 . In addition, the magnetic field lines of the third magnetic field M3 generated by the wireless antenna 23 easily enter the interior of the intermediate antenna 32 . Thereby, the controller 24 can communicate with the wireless communication host device 13 more reliably, and the communication range of the memory card 11 can be expanded. The cross-section of the inner side of the intermediate antenna 32 perpendicular to the direction in which the center Ax2 of the intermediate antenna 32 extends is larger than the cross-section of the inner side of the wireless antenna 23 perpendicular to the direction in which the center Ax1 of the wireless antenna 23 extends. Thereby, the magnetic field lines of the first magnetic field M1 easily pass through the inside of the intermediate antenna 32 , and electromagnetic induction is easily generated in the intermediate antenna 32 . Thereby, the controller 24 can communicate with the wireless communication host device 13 more reliably, and the communication range of the memory card 11 can be expanded. The middle antenna 32 is electrically separated from the wireless antenna 23 from each other. Thereby, for example, even if the intermediate antenna 32 is covered with a conductor, the controller 24 can communicate with the wireless communication host device 13 when the magnetic field lines of the first magnetic field M1 pass through the inside of the wireless antenna 23 . Therefore, the reduction of the communication range of the memory card 11 is suppressed. The intermediate antenna 32 is located between the wireless antenna 23 and the first outer surface 33 a exposed by the plurality of I/F terminals 22 . The memory card 11 that is a microSD card is generally used in a direction away from the user from below toward the first outer surface 33a on which the I/F terminal 22 is provided. Therefore, the user uses the memory card 11 so that the first outer surface 33 a faces the wireless communication host device 13 . With such adoption, the intermediate antenna 32 is disposed between the wireless antenna 23 and the wireless communication host device 13 . The magnetic field lines of the first magnetic field M1 generated by the wireless communication host device 13 change directions so as to expand radially from the intermediate antenna 32 through the interior of the intermediate antenna 32 , for example, by resonance. Since the magnetic field lines of the first magnetic field M1 whose directions are changed, and the magnetic field lines of the second magnetic field M2 generated by the intermediate antenna 32 pass through the inside of the wireless antenna 23, electromagnetic induction is generated in the wireless antenna 23, and the controller 24 can communicate with the wireless communication host device 13. . Therefore, since the intermediate antenna 32 changes the direction of the magnetic lines of force of the first magnetic field M1, the density of the magnetic lines of force inside the wireless antenna 23 increases, and the wireless antenna 23 can surely generate electromagnetic induction. Thereby, the controller 24 can communicate with the wireless communication host device 13 more reliably, and the communication range of the memory card 11 can be expanded. The conductor pattern 45 provided on the substrate 31 forms the intermediate antenna 32 . Thereby, the intermediate antenna 32 can be provided without increasing the number of parts, and the cost increase of the memory card 11 can be suppressed. The wireless antenna 23 is mounted on the substrate 31 . Thereby, for example, it is easy to arrange the wireless antenna 23 such that the direction in which the center Ax1 of the wireless antenna 23 extends and the direction in which the center Ax2 of the intermediate antenna 32 extends crosses each other. The resonance frequency of the intermediate antenna 32 is 10 MHz or more and 20 MHz or less. The frequency of the magnetic field according to the NFC specification is 13.56 MHz. Therefore, since the intermediate antenna 32 resonates with the first magnetic field M1 having a frequency (13.56 MHz) that conforms to the NFC standard, it is easy to concentrate the magnetic field lines of the first magnetic field M1. Thereby, since the first magnetic field M1 and the intermediate antenna 32 are likely to generate the second magnetic field M2, the controller 24 can more reliably communicate with the wireless communication host device 13, and the communication range of the memory card 11 can be expanded. A conductor such as a bonding pad may be present inside the intermediate antenna 32 in a plan view viewed in the Z-axis direction. Even if there is a conductor, electromagnetic induction is generated in the intermediate antenna 32 because the magnetic field lines of the first magnetic field M1 pass through the intermediate antenna 32 . (Second Embodiment) Hereinafter, a second embodiment will be described with reference to FIG. 5 . In addition, in the description of the following plural embodiments, the components having the same functions as the components already described are given the same reference numerals as the components previously described, and the description is omitted. In addition, the plural constituent elements to which the same reference numerals are attached are not limited to the common functions and properties, and may have different functions and properties according to each embodiment. FIG. 5 is an exemplary perspective view schematically showing the memory card 11 of the second embodiment. As shown in FIG. 5 , in the second embodiment, the memory card 11 further includes a film 51 . The membrane 51, for example, can also be referred to as a sealing body. The film 51 can be made of synthetic resin, for example, but can also be made of other materials such as paper. In the second embodiment, the intermediate antenna 32 is provided on the film 51 . Furthermore, the capacitor 49 of FIG. 2 is also provided on the film 51 and connected to the terminal of the intermediate antenna 32 . The film 51 is attached to the first outer surface 33 a of the protective case 33 by, for example, an adhesive applied to the film 51 . In addition, the film 51 may be attached to the first outer surface 33a by other means such as double-sided tape. In the memory card 11 of the second embodiment described above, the film 51 on which the intermediate antenna 32 is provided is attached to the first outer surface 33 a where the I/F terminal 22 is exposed. Thereby, the intermediate antenna 32 can be easily installed. Furthermore, an appropriate distance can be easily set between the intermediate antenna 32 and the wireless antenna 23 , and the magnetic field lines of the second magnetic field M2 generated by the intermediate antenna 32 can easily pass through the inside of the wireless antenna 23 . Thereby, the controller 24 can communicate with the wireless communication host device 13 more reliably, and the communication range of the semiconductor memory device can be expanded. (Third Embodiment) Hereinafter, a third embodiment will be described with reference to FIG. 6 . FIG. 6 is an exemplary perspective view schematically showing the intermediate antenna 32 of the third embodiment. As shown in FIG. 6 , the intermediate antenna 32 has a complex first part 61 , a complex second part 62 , and a complex third part 63 . The first portion 61 is formed by the conductor pattern 45 provided on the first layer 65 of the substrate 31 . The second portion 62 is formed by the conductor pattern 45 provided on the second layer 66 of the substrate 31 . The third portion 63 is formed by the conductor pattern 45 provided on the third layer 67 of the substrate 31 . The second layer 66 is located between the first layer 65 and the third layer 67 . In addition, other layers may be interposed between the first layer 65 and the second layer 66 or between the second layer 66 and the third layer 67 . The plurality of second portions 62 are electrically connected to the first portion 61 and the third portion 63 through holes 68, respectively. The plurality of first portions 61 , the plurality of second portions 62 , and the plurality of third portions 63 connected to each other through the holes 68 form a plurality of coils 69 connected in series. In other words, the intermediate antenna 32 includes a plurality of coils 69 . The plurality of coils 69 are arranged in a matrix on the X-Y plane. In addition, the arrangement of the plurality of coils 69 is not limited to this example. The plurality of coils 69 are formed by the first portion 61 , the second portion 62 , and the third portion 63 . By providing the first portion 61 , the second portion 62 , and the third portion 63 on the first layer 65 , the second layer 66 , and the third layer 67 of the substrate 31 , the coil 69 is formed into a spiral shape. In addition, the plurality of coils 69 may be formed in a spiral shape. After the magnetic field lines of the first magnetic field M1 pass through any one of the plurality of coils 69 , electromagnetic induction is generated in the intermediate antenna 32 including the plurality of coils 69 . Thereby, the plurality of coils 69 generate the second magnetic field M2. In the memory card 11 of the third embodiment described above, the wireless antenna 23 includes a plurality of coils 69 connected in series. Thereby, compared with the case where the wireless antenna 23 formed of a large coil is provided in the intermediate layer of the substrate 31, the internal space of the wireless antenna 23 is smaller. Therefore, it is possible to suppress the generation of air bubbles on the substrate 31 inside the wireless antenna 23 , thereby suppressing a decrease in the yield of the memory card 11 . (Fourth Embodiment) Hereinafter, a fourth embodiment will be described with reference to FIG. 7 . FIG. 7 is an exemplary plan view schematically showing the memory card 11 of the fourth embodiment. As shown in FIG. 7 , the memory card 11 of the fourth embodiment has two intermediate antennas 32 . The two middle antennas 32 are electrically separated from each other. The two intermediate antennas 32 respectively form individual resonant circuits C2. In a plan view from the Z-axis direction, one end 23 a of the wireless antenna 23 is located inside the outer edge 32 a of a middle antenna 32 . The other end portion 23b of the wireless antenna 23 is located inside the outer edge 32a of the other intermediate antenna 32 . The memory card 11 of the fourth embodiment described above has two intermediate antennas 32 that are electrically separated from each other. In a plan view from the Z-axis direction, one end 23 a of the wireless antenna 23 is located inside the outer edge 32 a of one intermediate antenna 32 , and the other end 23 b is located inside the outer edge 32 a of the other intermediate antenna 32 . As a result, if the magnetic field lines of the first magnetic field M1 pass through one of the two intermediate antennas 32 , electromagnetic induction can be generated inside the wireless antenna 23 . Thereby, the communication range of the memory card 11 can be expanded. (Fifth Embodiment) Hereinafter, a fifth embodiment will be described with reference to FIG. 8 . FIG. 8 is an exemplary plan view schematically showing a layer on which the intermediate antenna 32 of the substrate 31 of the fifth embodiment is provided. In FIG. 8, the wireless antenna 23 is indicated by a two-dot chain line. As shown in FIG. 8, the intermediate antenna 32 of the fifth embodiment is designed to be larger than the intermediate antenna 32 of the first embodiment. For example, the length of the intermediate antenna 32 in the X-axis direction is longer than the length of the wireless antenna 23 in the X-axis direction. By designing the middle antenna 32 to be larger, the inner cross section of the middle antenna 32 will be enlarged, and the inductance of the middle antenna 32 will be increased. Thereby, the communication range of the memory card 11 can be expanded. The intermediate antenna 32 has the conducting wire 71 formed by the conductor pattern 45 . The lead wire 71 has a first extension portion 71a, a second extension portion 71b, a third extension portion 71c, and a fourth extension portion 71d. The first extension portion 71a is an example of a part of the lead wire. The first extension 71a is adjacent to the second edge 31d of the substrate 31 and the second edge 33d of the protective case 33, and extends in the X-axis direction along the second edges 31d and 33d. The second extension portion 71b is spaced from the first extension portion 71a in the positive direction of the Y-axis, and extends in the X-axis direction. The third extension 71c and the fourth extension 71d extend in the Y-axis direction between the first extension 71a and the second extension 71b. The third extension portion 71c is adjacent to the third edge 31e of the substrate 31, and extends along the third edge 31e. The fourth extension portion 71d is spaced from the third extension portion 71c in the positive direction of the X-axis (the direction indicated by the arrow of the X-axis). The intermediate antenna 32 is formed in a substantially quadrangular loop by the first to fourth extending portions 71a, 71b, 71c, and 71d. In addition, the shape of the intermediate antenna 32 is not limited to this example. The wireless antenna 23 is located in the vicinity of the first extension portion 71a. In the present embodiment, the wireless antenna 23 extends along the first extension 71a, and overlaps a part of the first extension 71a in a plan view viewed in the direction in which the center Ax2 of the intermediate antenna 32 extends. In addition, the wireless antenna 23 may be spaced apart from the first extension portion 71 a in a plan view viewed in a direction in which the center Ax2 of the intermediate antenna 32 extends. The one end portion 23 a of the wireless antenna 23 is located inside the outer edge 32 a of the intermediate antenna 32 in a plan view viewed in a direction in which the center Ax2 of the intermediate antenna 32 extends. In addition, a part of the edge part 23a may be located in the inner side of the outer edge 32a, and the other part of the edge part 23a may be located in the outer side of the outer edge 32a. Furthermore, the other end portion 23 b of the wireless antenna 23 is located inside the outer edge 32 a of the intermediate antenna 32 in a plan view viewed in a direction in which the center Ax2 of the intermediate antenna 32 extends. The distance between the one end portion 23a of the wireless antenna 23 and the lead wire 71 is shorter than the distance between the other end portion 23b and the lead wire 71 . For example, the distance L1 between the end portion 23a and the third extension portion 71c is shorter than the distance L2 between the end portion 23b and the fourth extension portion 71d. In addition, the distances L1 and L2 are not limited to this example. The length L3 of the wireless antenna 23 overlapping the first extension 71a is shorter than the distance L2 between the end 23b of the wireless antenna 23 and the lead wire 71 in plan view in the direction in which the center Ax2 of the intermediate antenna 32 extends. In addition, the distance L2 and the length L3 are not limited to this example. The lead wires 71 include a plurality of first lead wires 75 and a plurality of second lead wires 76 . The second lead wire 76 is thicker than the first lead wire 75 . The first conducting wire 75 and the second conducting wire 76 are alternately connected to form the spiral-shaped intermediate antenna 32 . The first extension portion 71 a of the lead wire 71 is formed by the first lead wire 75 . The second extension portion 71b is formed by the second lead wire 76 . The third extension portion 71c and the fourth extension portion 71d are formed by the first lead wire 75 and the second lead wire 76, respectively. The conductor pattern 45 forms a plurality of dummy patterns 81 in addition to the intermediate antenna 32 . The dummy patterns 81 are arranged in a lattice shape (matrix shape) with a mutual interval on the inner side of the intermediate antenna 32 . The plurality of dummy patterns 81 are electrically separated from each other, and are electrically separated from the circuit C1 and the resonance circuit C2 of FIG. 2 . In addition, the dummy pattern 81 may, for example, be electrically connected to other conductors of the other dummy patterns 81 . The dummy pattern 81 is formed in a substantially circular shape, for example. In addition, the dummy pattern 81 may be other shapes. The distance between adjacent dummy patterns 81 is longer than the diameter of the dummy patterns 81 . Therefore, the density of the dummy pattern 81 inside the intermediate antenna 32 is lower than the density of the non-magnetic material inside the intermediate antenna 32 . The density of the dummy pattern 81 inside the center antenna 32 is set, for example, according to the communication performance of the center antenna 32 . By providing the dummy pattern 81, the formation of air bubbles on the substrate 31 is suppressed. Furthermore, by providing the dummy pattern 81, the strength of the substrate 31 is improved, and the first surface 31a and the second surface 31b of the substrate 31 can be formed more flat. In the memory card 11 of the fifth embodiment described above, the wireless antenna 23 is located in the vicinity of the lead wire 71 of the intermediate antenna 32 . That is, the wireless antenna 23 is arranged at a position where the density of the magnetic lines of force of the second magnetic field M2 generated by the intermediate antenna 32 is high. Thereby, since the induced electromotive force generated by the wireless antenna 23 increases, the communication range of the memory card 11 can be expanded. The wireless antenna 23 extends along the first extension 71 a of the lead wire 71 , and overlaps the first extension 71 a in a plan view viewed in the direction in which the center Ax2 of the intermediate antenna 32 extends. That is, the wireless antenna 23 is arranged at a position where the density of the magnetic lines of force of the second magnetic field M2 generated by the intermediate antenna 32 is higher. Thereby, since the induced electromotive force generated by the wireless antenna 23 increases, the communication range of the memory card 11 can be expanded. The magnetic field lines of the second magnetic field M2 generated in the vicinity of the conducting wire 71 enter the inside of the wireless antenna 23 from the gap of the winding wire of the wireless antenna 23 . Furthermore, due to the magnetic body 41 , the magnetic field lines of the second magnetic field M2 can easily enter the inside of the wireless antenna 23 . Therefore, the magnetic field lines of the second magnetic field M2 generated in the vicinity of the first extension portion 71 a generate an induced electromotive force based on electromagnetic induction in the wireless antenna 23 . Since the density of the magnetic lines of force of the second magnetic field M2 increases as it is closer to the lead wire 71 , more magnetic lines of force of the second magnetic field M2 can enter the gap between the coils of the wireless antenna 23 arranged near the lead wire 71 . Therefore, the wireless antenna 23 of the present embodiment superimposed on the first extension portion 71a can generate a larger induced electromotive force. At least a part of the end 23a of the wireless antenna 23 is located inside the outer edge 32a of the intermediate antenna 32, and the end 23b is located outside the outer edge 32a of the intermediate antenna 32 in a plan view in the direction in which the center Ax2 of the intermediate antenna 32 extends. Thereby, the magnetic field lines of the second magnetic field M2 entering the end portion 23a are increased, and the magnetic field lines of the second magnetic field M2 entering the end portion 23b are decreased. Therefore, in the wireless antenna 23, the induced electromotive force caused by the magnetic field lines entering from the end portion 23a and the induced electromotive force caused by the magnetic field lines entering from the end portion 23b can be suppressed from canceling each other out. Since the offset of the induced electromotive force is reduced, the induced electromotive force which is generated by the wireless antenna 23 and actuates the controller 24 increases, so that the communication range of the memory card 11 can be expanded. The distance L1 between the end portion 23a and the lead wire 71 is shorter than the distance L2 between the end portion 23b and the lead wire 71 . Thereby, the magnetic field lines of the second magnetic field M2 entering the end portion 23a are increased, and the magnetic field lines of the second magnetic field M2 entering the end portion 23b are decreased. Therefore, in the wireless antenna 23, the induced electromotive force caused by the magnetic field lines entering from the end portion 23a and the induced electromotive force caused by the magnetic field lines entering from the end portion 23b can be suppressed from canceling each other out. Since the offset of the induced electromotive force is reduced, the induced electromotive force which is generated by the wireless antenna 23 and actuates the controller 24 increases, so that the communication range of the memory card 11 can be expanded. The length L3 of the wireless antenna 23 overlapping the first extension portion 71 a is longer than the distance L2 between the end portion 23 b and the lead wire 71 when viewed in a plan view in the direction in which the center Ax2 of the intermediate antenna 32 extends. As a result, more parts of the wireless antenna 23 are arranged at positions where the density of the magnetic lines of force of the second magnetic field M2 is higher. Thereby, since the induced electromotive force generated by the wireless antenna 23 increases, the communication range of the memory card 11 can be expanded. The lead wire 71 includes a first lead wire 75 and a second lead wire 76 thicker than the first lead wire 75 . Thereby, the resistance of the second lead wire 76 is reduced, and the communication range of the memory card 11 can be expanded. Furthermore, the inner cross-section and inductance of the intermediate antenna 32 can be increased by the first conducting wire 75, and the communication range of the memory card 11 can be expanded. (Sixth Embodiment) Hereinafter, a sixth embodiment will be described with reference to FIG. 9 . FIG. 9 is an exemplary plan view schematically showing a layer on which the intermediate antenna 32 of the substrate 31 of the sixth embodiment is provided. As shown in FIG. 9, the lead wire 71 of 6th Embodiment has the recessed part 71e. The recessed portion 71 e is a part of the lead wire 71 recessed toward the inside of the intermediate antenna 32 . The recessed part 71e is provided in the corner of the 1st extension part 71a and the 4th extension part 71d. Therefore, by providing the concave portion 71e in the lead wire 71, the length of each of the first extension portion 71a and the fourth extension portion 71d is longer than that of the first extension portion 71a and the fourth extension portion 71d in the fifth embodiment. short. At least a part of the wireless antenna 23 intersects with the recessed portion 71e in a plan view viewed in a direction in which the center Ax2 of the intermediate antenna 32 extends. In another expression, the wireless antenna 23 extends across the concave portion 71e in a plan view viewed in a direction in which the center Ax2 of the intermediate antenna 32 extends. The region R is formed by the concave portion 71e. The region R is a region surrounded by the recessed portion 71e on the outer side of the outer edge 32a of the intermediate antenna 32 on the substrate 31 . In FIG. 9 , the region R is shown imaginatively by a two-dot chain line. The end portion 23b of the wireless antenna 23 is located in the region R. As shown in FIG. Thereby, the distance L2 between the end portion 23b and the lead wire 71 can be longer than the distance L2 in the fifth embodiment. In addition, the distance L2 may be made longer by passing the wireless antenna 23 through the area R while the end 23b is located outside the area R. The length of the radio antenna 23 in the X-axis direction and the length of the intermediate antenna 32 in the present embodiment are the same as the lengths of the radio antenna 23 in the X-axis direction and the length of the intermediate antenna 32 in the fifth embodiment. However, since the lead wire 71 has the concave portion 71e, the distance L2 is set to be longer. In the memory card 11 of the sixth embodiment described above, the lead wire 71 has the concave portion 71 e which is recessed toward the inner side of the intermediate antenna 32 . At least a part of the wireless antenna 23 intersects with the recessed portion 71e in a plan view viewed in a direction in which the center Ax2 of the intermediate antenna 32 extends. Therefore, the end portion 23b can be arranged in the region R formed by the concave portion 71e, or the wireless antenna 23 can be arranged at a position where the end portion 23b is separated from the lead wire 71 through the region R. Therefore, even when the memory card 11 is limited in area for wiring and mounting, for example, the end portion 23b can be arranged outside the outer edge 32a of the intermediate antenna 32 . In addition, although the recessed portion 71 e reduces the inner cross-section of the intermediate antenna 32 , other parts of the conducting wire 71 can be arranged to be larger than the inner cross-section of the intermediate antenna 32 . Therefore, the inner cross-section and inductance of the intermediate antenna 32 are increased, and the communication range of the memory card 11 can be expanded. In the first, second, fourth, fifth, and sixth embodiments, the intermediate antenna 32 is provided in one layer. However, the intermediate antenna 32 may be provided in plural layers. Therefore, even when the memory card 11 is limited in area for wiring and mounting, the number of coils of the intermediate antenna 32 can be increased, and the reduction of the inner cross-section of the intermediate antenna 32 can be suppressed. Thereby, the communication range of the memory card 11 can be expanded. In the plural embodiments described above, the wireless antenna 23 is a chip antenna, and the intermediate antenna 32 is formed by the conductor pattern 45 of the substrate 31 . However, the wireless antenna 23 may be formed by the conductor pattern 45 provided on the substrate 31 like the intermediate antenna 32 . In addition, the intermediate antenna 32 may be a chip antenna mounted on the substrate 31 like the wireless antenna 23 . Also in this case, the wireless communication controller 26 causes the second magnetic field M1 to pass through the intermediate antenna 32 when the magnetic field lines of the first magnetic field M1 directly pass through the inside of the wireless antenna 23 and the intermediate antenna 32 causes the second magnetic field M1 to pass through the intermediate antenna 32. The magnetic field M2 is generated, and the communication with the wireless communication host device 13 can be performed in both cases when the magnetic field lines of the second magnetic field M2 pass through the inside of the wireless antenna 23 . Thereby, the communication range of the memory card 11 can be expanded compared with the case where the intermediate antenna 32 is absent. According to at least one embodiment described above, the first loop antenna generates the second magnetic field based on electromagnetic induction by the first magnetic field. The second loop antenna generates an induced electromotive force based on electromagnetic induction by the second magnetic field. The controller can operate based on the induced electromotive force generated in the second loop antenna, and can communicate with the first external device through the second loop antenna. That is, the first loop antenna converts the first magnetic field into a second magnetic field suitable for electromagnetic induction by the second loop antenna. Thereby, the communication range of the semiconductor memory device can be expanded compared with the case where the first loop antenna is absent. Although several embodiments of the present invention have been described, these embodiments are merely illustrative and are not intended to limit the scope of the present invention. These novel embodiments can also be implemented in other various forms, and various omissions, substitutions, and changes can be made without departing from the gist of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and also include the equivalent scope of the invention described in the scope of the patent application.

11: Memory Card 12: Host device 13: Wireless communication host device 22: I/F terminal 23: Wireless Antenna 23a: End 24: Controller 31: Substrate 32: Intermediate Antenna 32a: outer edge 33: Protective case 33a: 1st outside 33c: The first edge 33d: 2nd edge 45: Conductor pattern 51: Film 69: Coil 71: Wire 71a: 1st extension 71e: Recess 75: 1st wire 76: 2nd wire Ax1,Ax2: Center M1: The first magnetic field M2: 2nd magnetic field L1, L2: distance L3: length

1 is a plan view schematically showing an example of a memory card according to the first embodiment.

2 is an exemplary block diagram schematically showing an example of the configuration of the memory card system including the first embodiment.

[ Fig. 3] Fig. 3 is a schematic cross-sectional view of the memory card according to the first embodiment, taken along the line F3-F3 in Fig. 1 .

[ Fig. 4] Fig. 4 is an exemplary perspective view schematically showing the memory card and the wireless communication host device according to the first embodiment.

[ Fig. 5] Fig. 5 is an exemplary perspective view schematically showing a memory card according to the second embodiment.

[ Fig. 6] Fig. 6 is an exemplary perspective view schematically showing an intermediate antenna according to the third embodiment.

[ Fig. 7] Fig. 7 is a plan view schematically showing an example of a memory card according to a fourth embodiment.

8 is an exemplary plan view schematically showing a layer on which the intermediate antenna of the substrate according to the fifth embodiment is provided.

[ Fig. 9] Fig. 9 is an exemplary plan view schematically showing a layer on which the intermediate antenna of the substrate of the sixth embodiment is provided.

11: Memory Card

22: I/F terminal

23: Wireless Antenna

23a: End

23b: end

24: Controller

25: Flash memory

26: Wireless Communication Controller

27: Memory Controller

28: Bridge Controller

31: Substrate

31b: Side 2

31c: The first edge

31d: 2nd edge

31e: 3rd edge

31f: 4th edge

32: Intermediate Antenna

32a: outer edge

33: Protective case

33b: 2nd outside

33c: The first edge

33d: 2nd edge

41: Magnetic body

45: Conductor pattern

Ax1,Ax2: Center

Claims (18)

A communication device comprising: a first loop antenna for generating a second magnetic field based on electromagnetic induction by a first magnetic field; a second loop antenna for generating an induced electromotive force based on electromagnetic induction by the second magnetic field; A controller that operates by induced electromotive force generated by the loop antenna, and performs communication with a first external device that generates the first magnetic field through the second loop antenna; the direction in which the center of the first loop antenna extends is related to the first 2. The directions in which the centers of the loop antennas extend intersect; the first loop antenna and the second loop antenna are electrically separated from each other. The communication device according to claim 1, wherein the second loop antenna can generate an induced electromotive force based on electromagnetic induction caused by the first magnetic field. The communication device according to claim 1, wherein one end portion of the second loop antenna is positioned inside the outer edge of the first loop antenna in a plan view viewed in a direction in which the center of the first loop antenna extends. The communication device according to claim 1 or claim 2, wherein the cross section of the inner side of the first loop antenna perpendicular to the direction in which the center of the first loop antenna extends is more perpendicular to the direction in which the center of the second loop antenna extends The cross section of the inner side of the second loop antenna is also larger. The communication device according to claim 1 or claim 2, further comprising: a protective case that has an outer surface and covers the controller; a plurality of terminals exposed on the outer surface; The controller communicates with the second external device through the terminal, and the first loop antenna is located between the second loop antenna and the outer surface. The communication device according to claim 1 or claim 2, further comprising: a substrate provided with a conductor pattern; the controller is mounted on the substrate; and the conductor pattern forms the first loop antenna. The communication device according to claim 6, wherein the first loop antenna includes a plurality of coils connected in series. The communication device according to claim 6, wherein the second loop antenna is mounted on the substrate. The communication device of claim 1 or claim 2, further comprising: a protective case having an outer surface and covering the controller; a plurality of terminals exposed on the outer surface; a film provided with the first loop antenna; wherein the controller Communication with the second external device is performed through the terminal; the film is attached to the outer surface. The communication device according to claim 1 or claim 2, wherein the resonance frequency of the first loop antenna is 10 MHz or more and 20 MHz or less. The communication device according to claim 1, wherein the second loop antenna is located in the vicinity of the conducting wire of the first loop antenna. The communication device according to claim 11, wherein the second loop antenna extends along a portion of the conducting wire and overlaps with a portion of the conducting wire in a plan view viewed in a direction in which the center of the first loop antenna extends. The communication device according to claim 12, wherein the second loop antenna has: a first end portion, a second end portion located on the opposite side of the first end portion; In plan view, at least a part of the first end portion is located inside the outer edge of the first loop antenna, and the second end portion is located outside the outer edge of the first loop antenna. The communication device of claim 13, wherein the distance between the first end portion and the lead wire is shorter than the distance between the second end portion and the lead wire. The communication device according to claim 13, wherein the length of the second loop antenna overlapping a part of the conducting wire in a plan view viewed in a direction in which the center of the first loop antenna extends is longer than a length between the second end portion and the conducting wire The distance between them is still long. The communication device according to claim 13, wherein the conducting wire has a concave portion recessed toward the inner side of the first loop antenna; and in a plan view viewed in a direction in which the center of the first loop antenna extends, at least a part of the second loop antenna is connected to the The aforementioned recesses intersect. The communication device according to claim 11, wherein the conducting wire includes a first conducting wire and a second conducting wire that is thicker than the first conducting wire. A communication device comprising: a protective case having an outer surface, a first edge, and a second edge located on the opposite side of the first edge; a plurality of terminals exposed on the outer surface and arranged along the first edge; and a first loop antenna ; a second loop antenna extending along the second edge; covered by the protective case, communicating with the first external device through the second loop antenna, and communicating with the second external device through the terminal a controller; wherein the direction in which the center of the first loop antenna extends intersects the direction in which the center of the second loop antenna extends; the first loop antenna is located between the second loop antenna and the outer surface; The one end portion of the second loop antenna is positioned inside the outer edge of the first loop antenna in a plan view viewed from a direction in which the center of the loop antenna extends.

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