KR20110057840A - Connecting port system - Google Patents

Abstract

PURPOSE: A connection port system is provided to transmit and receive a signal from an external device through a connection port by equipping an interface unit which is connected to an RFID chip. CONSTITUTION: A connection port(410) is connected to an external device. An interface unit(420) is connected to the input/output port of the connection port. An RFID(Radio Frequency ID) chip(100) is connected to the interface unit and includes a security process unit(250). The interface unit controls the connection state of the input/output port according to a security control signal that is outputted from the RFID chip. The RFID chip controls the security control signal according to the radio signal.

Description

Connecting port system

The present invention relates to a connection port system including a connection interface capable of transmitting and receiving signals by connecting to an external device such as a computer through a connection port.

RFID (Radio Frequency IDentification Tag Chip) is a contactless automatic identification method that communicates with an RFID reader by attaching an RFID tag to an object to be identified and automatically transmitting and receiving it by using a wireless signal. To provide technology. As RFID is used, it is possible to compensate for the disadvantages of the conventional automatic identification technology, barcode and optical character recognition technology.

Recently, RFID tags have been used in various cases, such as logistics management systems, user authentication systems, electronic money systems, transportation systems.

For example, in the logistics management system, cargo classification or inventory management is performed using an integrated circuit (IC) tag in which data is recorded instead of a delivery slip or a tag. In the user authentication system, admission management and the like are performed using an IC card that records personal information and the like.

Meanwhile, a nonvolatile ferroelectric memory may be used as a memory used for an RFID tag.

In general, nonvolatile ferroelectric memory, or ferroelectric random access memory (FeRAM), has a data processing speed of about dynamic random access memory (DRAM) and is attracting attention as a next-generation memory device because of its characteristic that data is preserved even when the power is turned off. have.

The FeRAM is a device having a structure almost similar to that of a DRAM, and uses a ferroelectric capacitor as a memory device. Ferroelectrics have a high residual polarization characteristic, and as a result, the data is not erased even when the electric field is removed.

1 is an overall configuration diagram of a general RFID device.

The RFID device according to the related art largely includes an antenna unit ANT, an analog unit 10, a digital unit 20, and a memory unit 30.

Here, the antenna ANT serves to receive a radio signal transmitted from an external RFID reader. The wireless signal received through the antenna unit ANT is input to the analog unit 10 through the antenna pads 11 and 12.

The analog unit 10 amplifies the input wireless signal to generate a power supply voltage VDD which is a driving voltage of the RFID tag. The operation command signal is detected from the input wireless signal, and the command signal CMD is output to the digital unit 20. In addition, the analog unit 10 senses the output voltage VDD and outputs a power-on reset signal POR and a clock CLK to the digital unit 20 for controlling the reset operation.

The digital unit 20 receives the power supply voltage VDD, the power-on reset signal POR, the clock CLK, and the command signal CMD from the analog unit 10, and outputs a response signal RP to the analog unit 10. The digital unit 20 also outputs the address ADD, input / output data I / O, control signal CTR, and clock CLK to the memory unit 30.

In addition, the memory unit 30 reads / writes data using a memory element and stores the data.

Here, the RFID device uses a frequency of several bands, the characteristics of which vary depending on the frequency band. In general, the lower the frequency band, the slower the recognition speed, the RFID device operates in a short distance, and is less affected by the environment. On the contrary, the higher the frequency band, the faster the recognition speed and the longer the distance is affected by the environment.

The present invention has the following object.

First, an object of the present invention is to provide an interface unit connected to an RFID chip so as to transmit and receive a signal through an external device and a connection port.

Second, an object of the present invention is to set a security function on an RFID chip to selectively control an activation state of a connection port connected to an external device such as a computer so that a separate security program is unnecessary.

Third, an object of the present invention is to enable a security function to be set using a radio signal in a security processing unit inside an RFID chip.

The present invention for achieving the above object, Port for connecting to an external device (Port); An interface unit connected to an input / output terminal of the connection port; And an RFID chip connected to the interface unit, wherein the interface unit controls a connection state of the input / output terminal according to a security control signal output from the RFID chip.

The present invention has the following effects.

First, the present invention is provided with an interface unit connected to the RFID chip, not only can transmit and receive a wireless signal through the RFID reader and the antenna, there is an advantage that the signal can be transmitted and received through the connection port with the external device.

Secondly, the present invention sets a security function on an RFID chip to selectively control an activation state of a connection port connected to an external device such as a computer so that a separate security program is unnecessary.

Third, the present invention provides an effect of easily setting a security function using a radio signal to the security processing unit inside the RFID chip.

Preferred embodiments of the present invention are for purposes of illustration, and those skilled in the art can make various modifications, changes, substitutions and additions through the spirit and scope of the appended claims, and such modifications may be made by the following claims. Should be seen as belonging to.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 shows a mobile phone 2 comprising a connection port system 1 according to the invention.

Connection port system 1 according to the invention can be included in the mobile phone (2). The connection port system 1 according to the invention communicates wirelessly with i) a connection port 40 for connecting a cellular phone 2 and an external device, for example, a PC 3 by wire, and ii) a PC 3. It includes a circuit portion (not shown) for. That is, the mobile phone 2 may be connected to an external device by wire or wirelessly through the connection port system 1.

Specifically, the internal circuit of the mobile phone 2 is connected to the connection port system 1, and the connection port system 1 is connected to an external device through a connection cable 4 connected to the connection port 40 and the connection port 40. Is connected to the PC 3. As a result, the internal circuit of the cellular phone 2 can transmit and receive data to and from the PC 3 by wire.

On the other hand, the internal circuit of the mobile phone 2 is connected to the connection port system 1, the connection port system 1 includes a circuit portion (not shown) capable of wireless communication. Since the connection port system 1 includes an RFID chip, it can wirelessly communicate with an external device, for example, the PC 3, which includes an RFID reader.

As described above, the device equipped with the connection port system 1 of the present invention may have an advantage that i) communicates with an external device via a connection port 40 by wire, or ii) wirelessly via a wireless signal. There is this.

Although the connection port system 1 is illustrated as being mounted inside the mobile phone 2, the present invention is not limited thereto, and most electronic devices, for example, PDAs, PMPs, MP3 players, Can be attached to devices such as digital cameras.

3 is a block diagram of a radio frequency identification (RFID) chip 100 according to the present invention.

The RFID chip 100 includes an antenna ANT, a voltage multiplier 110, a modulator 120, a demodulator 130, a power on reset unit 140, a clock generation A clock generator 150 includes a clock generator 150, a digital unit 200, and a memory unit 300. Here, the digital unit 200 includes a security processing unit 250.

The antenna ANT receives a radio signal (RF) transmitted from an RFID reader. The radio signal received by the RFID chip 100 is input to the RFID chip 100 through antenna pads ANT (+) and ANT (−).

The voltage amplification unit 110 rectifies and boosts the radio signal applied from the antenna ANT to generate a power supply voltage VDD which is a driving voltage of the RFID chip 100.

The modulator 120 modulates the response signal RP input from the digital unit 200 and transmits the modulated response signal RP to the antenna ANT. The demodulator 130 demodulates the radio signal input from the antenna ANT according to the output voltage of the voltage amplifier 110 and outputs the command signal CMD to the digital unit 200.

In addition, the power-on reset unit 140 detects the power supply voltage generated by the voltage amplifier 110 and outputs a power-on reset signal POR for controlling the reset operation to the digital unit 200. Here, the power-on reset signal POR rises together with the power supply voltage while the power supply voltage transitions from the low level to the high level, and then transitions from the high level to the low level when the power supply voltage is supplied to the power supply voltage level VDD. Means a signal to reset the internal circuit.

The clock generator 150 supplies the clock CLK for controlling the operation of the digital unit 200 according to the power voltage generated by the voltage amplifier 110 to the digital unit 200.

In addition, the digital unit 200 receives a power supply voltage VDD, a power-on reset signal POR, a clock CLK, and a command signal CMD, interprets the command signal CMD, and generates control signals and processing signals. The digital unit 200 outputs a response signal RP corresponding to the control signal and the processing signals to the modulator 120. The digital unit 200 also outputs the address ADD, data I / O, control signal CTR, and clock CLK to the memory unit 300.

Here, the address ADD is a signal indicating which memory cell to store input / output data I / O, that is, a signal including location information of the memory cell. The control signal CTR refers to one or more signals used to control read / write operations on input / output data I / O to a memory cell.

The chip enable signal CE refers to a signal for activating the operation of the memory unit 300. The write enable signal WE refers to a signal that activates a write operation when writing data to a memory cell. The output enable signal OE refers to a signal that activates an output operation of read data when reading data stored in a memory cell.

In addition, the security processor 250 outputs a security control signal Sec_con <0: m> for controlling the security function according to the command signal CMD applied from the demodulator 130. When a signal for setting a security function from an external RFID reader is applied through the antenna ANT, a command signal CMD for setting the security function through the voltage amplifier 110 and the demodulator 130 is transmitted to the security processor 250. Is entered. Therefore, the RFID chip 100 can easily set a security function to the security processing unit 250 according to a wireless signal applied from the outside.

In addition, the memory unit 300 includes a plurality of memory cells, each of which serves to write data to the storage device and to read data stored in the storage device.

Here, the memory unit 300 includes a nonvolatile memory area. A nonvolatile ferroelectric memory (FeRAM) may be used as the nonvolatile memory region. Such FeRAM has a data processing speed of about DRAM. In addition, FeRAM has a structure almost similar to DRAM, and has a high residual polarization characteristic of the ferroelectric by using a ferroelectric as the material of the capacitor. Due to this residual polarization characteristic, data is not erased even when the electric field is removed.

4 is a configuration diagram of a connection port system according to the present invention.

The present invention includes an RFID chip 100, an interface unit 420, a system controller 400, and a connection port 410. This connection port system can be implemented on one chip. Here, the RFID chip 100 includes a security processor 250 therein.

In addition, the connection port 410 is preferably made of a universal serial bus (USB) port. In addition, in the present invention, the connection port 410 may be a USB port, a 1394 port, a serial port, and the like, and the type of the connection port is not limited.

The system control unit 400 is connected to the connection port 410 and the power supply terminals (VDD, GND), and through the input / output terminals (D-, D +). The RFID chip 100 is commonly connected to the system controller 400, the connection port 410, and the power terminals VDD and GND.

The security processor 250 outputs a security control signal Sec_con <0: m> to the interface unit 420. The interface unit 420 is connected to the input / output terminals D- and D + of the connection port 410.

The interface unit 420 selectively controls the connection state of the input / output terminals D + and D- of the connection port 410 according to the security control signal Sec_con <0: m> applied from the security processing unit 250.

The system controller 400 controls the operation of the RFID chip 100. The system controller 400 is connected to the RFID chip 100 and the power terminals (VDD, GND). Accordingly, it is possible to selectively control the power supplied to the RFID chip 100 to control whether the RFID chip 100 is driven.

In addition, the connection port 410 may be connected to a connection terminal included in an external device such as a computer. When the input / output terminals D + and D- of the connection port 410 and the connection terminals of the external device are connected to each other, an external input signal is input from the external device through the input / output terminals D + and D-. In addition, the security control signal Sec_con <0: m> output from the RFID chip 100 is transmitted to the interface unit 420. The connection state of the input / output terminals D + and D- of the connection port 410 is selectively blocked by the signal output from the interface unit 420.

The interface unit 420 includes a security controller 421 and a driver 422.

Here, the security controller 421 selectively activates the security enable signal SEN according to the security control signal Sec_con <0: m> output from the RFID chip 100.

The driver 422 includes an NMOS transistor N1 which is a switching element. The NMOS transistor N1 is connected between the input / output terminals D + and D-, and a security enable signal SEN is applied through the gate terminal. Accordingly, when the security enable signal SEN is activated to a high level, the NMOS transistor N1 is turned on so that the input / output terminals D + and D- are connected to each other.

The driving unit 422 becomes a high resistance state when the connection between the input / output terminals D + and D- is open, and the connection between the input / output terminals D + and D- is short. In this case, a low resistance state is obtained. Therefore, when both ends of the input / output terminals D + and D- are connected to each other, the input / output terminals D + and D- may not read or write information to an external device such as a computer through the connection port 410.

5 is an operation timing diagram of the connection port system according to FIG. 4.

First, a security command is input to the RFID chip 100 through a antenna ANT as a radio signal. Then, the security command is demodulated through the voltage amplifier 110 and the demodulator 130, and the command signal CMD is input to the security processor 250.

The security processing unit 250 interprets the command signal CMD applied from the demodulation unit 130, and when the command corresponds to the security command, activates and outputs the security control signal Sec_con <0: m> to a valid state. do.

Thereafter, when the security control signal Sec_con <0: m> is activated and authorized from the security processing unit 250, the security controller 421 activates and outputs the security enable signal SEN to a high level. At this time, when the security enable signal SEN becomes a high level, the security enable state.

Next, when the security enable signal SEN goes high, the NMOS transistor N1 is turned on. As a result, the connection between the input / output terminal D + and the input / output terminal D− becomes short and becomes a low resistance state. Therefore, the signals between the input / output terminals D + and D- are equalized to lose the characteristics of the signals, thereby making data communication impossible between the input / output terminals D + and D-. That is, when the security activation state is set, the information transmission line of the connection port 410 is inactivated.

6 is another embodiment of a connection port system according to the present invention.

The present invention includes an RFID chip 100, an interface unit 520, a system controller 500, and a connection port 510. Such an RFID system may be implemented on one chip. Here, the RFID chip 100 includes a security processor 250 therein.

In addition, the connection port 510 is preferably made of a universal serial bus (USB) port. In addition, in the present invention, the connection port 510 may be a USB port, a 1394 port, a serial port, and the like, and the type of the connection port is not limited.

The system controller 500 is connected to the connection port 510 and the power terminals (VDD, GND), and through the input / output terminals (D-, D +). The RFID chip 100 is commonly connected to the system controller 500, the connection port 510, and the power terminals VDD and GND.

The security processor 250 outputs a security control signal Sec_con <0: m> to the interface unit 520. The interface unit 520 is connected to the input / output terminals D- and D + of the connection port 510.

The interface unit 520 selectively controls the connection state of the input / output terminals D + and D- of the connection port 510 according to the security control signal Sec_con <0: m> applied from the security processing unit 250.

The system controller 500 controls the operation of the RFID chip 100. The system controller 500 is connected to the RFID chip 100 and the power terminals (VDD, GND). Accordingly, it is possible to selectively control the power supplied to the RFID chip 100 to control whether the RFID chip 100 is driven.

In addition, the connection port 510 may be connected to a connection terminal included in an external device such as a computer. When the input / output terminals D + and D- of the connection port 510 and the connection terminals of the external device are connected to each other, an external input signal is input from the external device through the input / output terminals D + and D-. In addition, the security control signal Sec_con <0: m> output from the RFID chip 100 is transmitted to the interface unit 520. The connection state of the input / output terminals D + and D- of the connection port 510 is selectively shorted by the signal output from the interface unit 520.

The interface unit 520 includes a security controller 521 and a driver 522.

Here, the security controller 521 selectively activates the security enable signal SEN according to the security control signal Sec_con <0: m> output from the RFID chip 100.

The driving unit 522 includes NMOS transistors N2 and N3 which are switching means. The NMOS transistor N2 is connected between the connection nodes of the input / output terminal D- and a security enable signal SEN is applied through the gate terminal. In addition, the NMOS transistor N3 is connected between the connection nodes of the input / output terminal D +, and a security enable signal SEN is applied through the gate terminal.

Accordingly, when the security enable signal SEN is activated at a low level, the NMOS transistors N2 and N3 are turned off. Therefore, the input / output terminals D + are separated from each other, and the input / output terminals D− are separated from each other. In this case, both ends of the input / output terminals D + and D- are separated from each other, so that information (information) cannot be written to or read from an external device such as a computer through the connection port 510.

7 is an operation timing diagram of the connection port system according to FIG. 6.

First, a security command is input to the RFID chip 100 through a antenna ANT as a radio signal. Then, the security command is demodulated through the voltage amplifier 110 and the demodulator 130, and the command signal CMD is input to the security processor 250.

The security processing unit 250 interprets the command signal CMD applied from the demodulation unit 130, and when the command corresponds to the security command, activates and outputs the security control signal Sec_con <0: m> to a valid state. do.

Thereafter, when the security control signal Sec_con <0: m> is activated and applied from the security processing unit 250, the security control unit 521 activates and outputs the security enable signal SEN to a low level. At this time, when the security enable signal SEN becomes the low level, the security enable state.

Next, when the security enable signal SEN goes low, the NMOS transistors N2 and N3 are turned off at the same time. As a result, the connection between the input / output terminal D + and the input / output terminal D− is open. That is, the input / output terminal D + is short-circuited in its connection, and the input / output terminal D- is in a short-circuited state. Therefore, the input / output terminals D + and D- are in a state where the data buses are separated from each other, and data communication between the input / output terminals D + and D- is impossible. That is, when the security activation state is set, the information transmission line of the connection port 410 is deactivated.

8 is another embodiment of a connection port system according to the present invention.

The present invention includes an RFID chip 100, an interface unit 620, a system controller 600, and a connection port 610. Such an RFID system may be implemented on one chip. Here, the RFID chip 100 includes a security processor 250 therein.

In addition, the connection port 610 is preferably made of a universal serial bus (USB) port. In addition, in the present invention, the connection port 610 may be a USB port, a 1394 port, a serial port, and the like, and the type of the connection port is not limited.

The system control unit 600 is connected to the connection port 610 and the power terminals (VDD, GND), and through the input / output terminals (D-, D +). The RFID chip 100 is commonly connected to the system controller 600, the connection port 610, and the power terminals VDD and GND.

The security processor 250 outputs a security control signal Sec_con <0: m> to the interface unit 620. The interface unit 620 is connected to the input / output terminals D- and D + of the connection port 610.

The interface unit 620 selectively controls the connection state of the input / output terminals D + and D- of the connection port 610 according to the security control signal Sec_con <0: m> applied from the security processing unit 250.

The system controller 600 controls the operation of the RFID chip 100. The system controller 600 is connected to the RFID chip 100 and the power terminals (VDD, GND). Accordingly, it is possible to selectively control the power supplied to the RFID chip 100 to control whether the RFID chip 100 is driven.

In addition, the connection port 610 may be connected to a connection terminal included in an external device such as a computer. When the input / output terminals D + and D- of the connection port 610 and the connection terminals of the external device are connected to each other, an external input signal is input from the external device through the input / output terminals D + and D-. In addition, the security control signal Sec_con <0: m> output from the RFID chip 100 is transmitted to the interface unit 620. The input / output terminals D + and D- of the connection port 610 are selectively pulled down by the signal output from the interface unit 620.

The interface unit 620 includes a security controller 621 and a driver 622.

Here, the security controller 621 selectively activates the security enable signal SEN according to the security control signal Sec_con <0: m> output from the RFID chip 100.

In addition, the driver 622 includes NMOS transistors N4 and N5 which are pull-down means. The NMOS transistor N4 is connected between the input / output terminal D- and the ground voltage terminal, and a security enable signal SEN is applied through the gate terminal. In addition, the NMOS transistor N3 is connected between the input / output terminal D + and the ground voltage terminal, and a security enable signal SEN is applied through the gate terminal.

Accordingly, when the security enable signal SEN is activated to a high level, the NMOS transistors N2 and N3 are turned on. Therefore, the input / output terminal D + is pulled down to the ground voltage level, and the input / output terminal D- is pulled down to the ground voltage level. In this case, the input / output terminals D + and D- are all driven at a pulldown voltage level, so that information (information) cannot be written or read to an external device such as a computer through the connection port 610.

9 is an operation timing diagram of the connection port system according to FIG. 8.

First, a security command is input to the RFID chip 100 through a antenna ANT as a radio signal. Then, the security command is demodulated through the voltage amplifier 110 and the demodulator 130, and the command signal CMD is input to the security processor 250.

The security processing unit 250 interprets the command signal CMD applied from the demodulation unit 130, and when the command corresponds to the security command, activates and outputs the security control signal Sec_con <0: m> to a valid state. do.

Thereafter, when the security control signal Sec_con <0: m> is activated and authorized from the security processing unit 250, the security controller 521 activates and outputs the security enable signal SEN to a high level. At this time, when the security enable signal SEN becomes a high level, the security enable state.

Next, when the security enable signal SEN goes high, the NMOS transistors N4 and N5 are turned on at the same time. Accordingly, both input / output terminals D + are pulled down to the ground voltage level. Therefore, the input / output terminals D + and D- are all driven at the pull-down voltage level, so that data communication between the input / output terminals D + and D- is impossible. That is, when the security activation state is set, the information transmission line of the connection port 410 is inactivated.

In general, mobile devices such as mobile phones and notebook PCs, and fixed electronic devices of desktop PCs are provided with data exchange ports such as USB ports. These data interface ports enable data exchange with external devices.

Therefore, in order to set the security of such a device, the active state and the inactive state of the connection port can be implemented using the RFID chip 100. When the security of the connection port is set using the RFID chip 100, the configuration is simple and the security state can be easily set using wireless communication. Accordingly, a separate security program is unnecessary when setting security, and a separate sticker sealing operation is unnecessary.

1 is an overall configuration diagram of a general RFID device.

2 is a view for explaining a connection port system according to the present invention.

3 is a block diagram of an RFID chip of the present invention.

4 is a configuration diagram of a connection port system according to a first embodiment of the present invention.

5 is an operation timing diagram relating to the connection port system of FIG.

6 is a configuration diagram of a connection port system according to a second embodiment of the present invention.

7 is an operation timing diagram relating to the connection port system of FIG.

8 is a configuration diagram of a connection port system according to a third embodiment of the present invention.

9 is an operation timing diagram relating to the connection port system of FIG. 8;

Claims (21)

A connection port connected to an external device; An interface unit connected to an input / output terminal of the connection port; And An RFID chip connected to the interface unit, And the interface unit controls a connection state of the input / output terminal according to a security control signal output from the RFID chip. The connection port system of claim 1, wherein the RFID chip controls a state of the security control signal according to a wireless signal applied from the outside. The connection port system of claim 1, wherein the RFID chip includes a security processor configured to detect a security command from a wireless signal applied from the outside and output the security control signal. The method of claim 1, wherein the interface unit A security controller configured to output a security enable signal according to the security control signal; And And a driver configured to control a connection state of the input / output terminals according to the security enable signal. The method of claim 4, wherein the driving unit And a first switching element for selectively shorting a connection between a first input / output terminal and a second input / output terminal among the input / output terminals according to the security enable signal. The method of claim 5, wherein the first switching device And a first NMOS transistor connected between the first input / output terminal and the second input / output terminal to receive the security enable signal through a gate terminal. 6. The connection port system of claim 5, wherein the first switching element is turned on when the security enable signal is at a high level. The method of claim 4, wherein the driving unit Switching means for selectively shorting the connection of the input / output terminals in accordance with the security enable signal. The method of claim 8, wherein the switching means A second switching element for selectively shorting a connection node of a third input / output terminal among the input / output terminals; And And a third switching element for selectively shorting a connection node of a fourth input / output terminal of the input / output terminals. 10. The connection port system of claim 9, wherein the second switching element comprises a second NMOS transistor coupled between the third input / output terminals to which the security enable signal is applied through a gate terminal. 10. The connection port system of claim 9, wherein the third switching element comprises a third NMOS transistor connected between the fourth input / output terminals to which the security enable signal is applied through a gate terminal. 9. The connection port system of claim 8, wherein the switching means is turned off when the security enable signal is at a low level. The method of claim 4, wherein the driving unit And pull-down means for pull-down driving the input / output terminals according to the security enable signal. The method of claim 13, wherein the switching means A fourth switching element configured to pull down the fifth input / output terminal among the input / output terminals; And And a fifth switching element configured to pull down the sixth input / output terminal among the input / output terminals. 15. The connection of claim 14, wherein the fourth switching device comprises a fourth NMOS transistor connected between the fifth input / output terminal and a ground voltage terminal to which the security enable signal is applied through a gate terminal. Port system. 15. The connection of claim 14, wherein the fifth switching device comprises a fifth NMOS transistor connected between the sixth input / output terminal and a ground voltage terminal to which the security enable signal is applied through a gate terminal. Port system. 14. The connection port system of claim 13, wherein said switching means is turned on when said security enable signal is at a high level. The method of claim 1, wherein the RFID chip A demodulator for demodulating a radio signal applied from the outside; A modulator for modulating the response signal and outputting the modulated response signal; A digital unit for processing a command signal applied from the demodulator and generating the response signal; And a memory unit for storing the information processed by the digital unit. 19. The connection port system of claim 18, wherein the memory portion comprises a ferroelectric memory element. The connection port system of claim 1, further comprising a system controller connected to the connection port and the input / output terminal. The connection port system of claim 20, wherein the system controller is connected to the RFID chip and a power terminal.

Images