AT519053A1 - Product with printed electronic circuit for radio communication - Google Patents

Abstract

Shown is a product made from, preferably flat, starting material, in particular paper, cardboard, paperboard or plastic film, the product being particularly imprinted with information, the product comprising at least one printed electronic circuit and wherein the product comprises at least one antenna system for has the radio communication with a mobile electronic device (M) in the near field. In order to be able to transmit different information to a mobile electronic device (M) of the user in a simple manner, it is proposed that the electronic circuit has at least one first printed operating field (S), wherein in the actuated state of the first actuating field a first signal is applied to the antenna system that differs from a signal on the antenna system when the actuation field is not actuated.

Description

Product with printed electronic circuit for radio communication

FIELD OF THE INVENTION

The invention relates to a product made from, preferably flat, starting material, in particular paper, cardboard, cardboard or plastic film, wherein the product is in particular printed with information, wherein the product has at least one printed electronic circuit, and wherein the product at least one antenna system for radio communication with a mobile electronic device in the near field. The invention also includes a method for transmitting information with such a product using a mobile electronic device.

In this case, the starting material - for example, and not necessarily in this order - printed with information, printed with the electronic circuit, cut and optionally folded. Usually this product will be made of paper, but it can also have parts made of film.

The product may be a package, such as a box that is printed, cut or punched, folded and finally given its final shape by gluing or tabbing. In addition to the function of packaging and thus protection, the product according to the invention can additionally serve communication and marketing.

The product may also be another common printed carrier for marketing, communication and information, such as a so-called flyer, poster or advertising leaflet, newspaper, sticker, label, desk pads, or even just the envelope of such a product. These printed carriers will usually consist of paper, cardboard or foil or combinations thereof.

The starting material may be according to paper, cardboard, cardboard or plastic film. Plastic film, colloquially also called plastic film, is a thin (usually <1 mm thick) sheet of plastic. Typical film thicknesses are in the range below 0.1 mm. Frequently, multilayer composites are also made from a combination of different plastics. Also other printable

Starting materials can be used, such as metal foils, also again either alone or in combination with the starting materials already mentioned.

Of course, combinations of paper, cardboard or cardboard covered with plastic films under the invention, such as when the plastic film for coating paper, cardboard or paperboard is used, in which case the coated product is printed.

Radio technology in the near field includes, in particular, RFID technology, to which NFC technology and, in a broader sense, Bluetooth technology can also be counted. The range of transmission of signals in NFC technology is in the range of a few centimeters, while other RFID and Bluetooth technologies can be achieved in passive operation up to several meters. Active (with its own power supply on the product) can be communicated over much longer distances.

Of course, the product may also contain a plurality of antenna systems, such as several transmit antennas, or other antennas or antenna systems for other purposes.

STATE OF THE ART

It is known to provide advertising billboards with NFC chips so that a person holds a mobile NFC-enabled electronic device, such as a mobile phone (smartphone) or a tablet PC, close to the NFC chip and information stored on the NFC chip is transmitted to the mobile electronic device using the NFC protocol. This can e.g. additional information that is not included in the information printed on the poster. However, only the same given information can always be retrieved from the NFC chip, that is, the NFC chip always sends the same signal to each mobile device.

From GR 2013/100113 it is known to attach self-adhesive labels with printed electronic circuits to bottles to detect distortions of the content. The labels can be read by the consumer using an NFC-enabled smartphone. Again, only the same signal or the same information can always be sent to any mobile device.

PRESENTATION OF THE INVENTION

It is therefore an object of the invention to provide a product made of preferably flat starting material, with which product different information can be transmitted to a user's mobile electronic device in a simple manner.

The invention relates to a product made from, preferably flat, starting material, in particular paper, cardboard, cardboard or plastic film, wherein the product is printed in particular with information, wherein the product has at least one printed electronic circuit, and wherein the product at least one Antenna system for the radio communication with a mobile electronic device in the near field has.

The object is achieved in accordance with claim 1 in such a way that the electronic circuit has at least one first printed actuating field, wherein in the actuated state of the first actuating field a first signal is applied to the antenna system, which differs from a signal at the antenna system (of the product) when the actuating field is not actuated.

In this way, the user can select a specific (first) signal by actuating the actuation field, which then causes a specific (first) action on the user's mobile device. The field of operation is via the printed circuit directly to the antenna system or e.g. connected to an NFC chip such that upon actuation of the actuation field (e.g., by placing the user's finger on) the signal on the antenna system is fixed directly or via a logic circuit or a chip. If the actuation field is no longer actuated (for example, the user lifts the finger away from the operating field), the first signal is no longer present at the antenna system and is no longer transmitted to the mobile electronic device. Either no signal from the antenna system can then be sent, or another signal can be sent, as is customary in the prior art, for example a signal stored in an NFC chip.

So that the product provides the user with a greater choice, it can be provided that the electronic circuit has at least a second printed actuating field, so that upon actuation of the second operating field on the antenna system, a second signal is present, which differs from the first signal. Of course, the product may also have three, four or even more fields of activity, the operation of which in turn each cause its own signal on the antenna system.

The actuation field may, for example, comprise a printed switch which is in the actuated state of the actuation field in the closed state. The switch then closes a circuit whose components generate the associated signal.

The first, second, or further signal of the respective actuation field is preferably a static signal, that is to say it is repeated after one or, as a rule, several period durations of the fundamental frequency. It does not matter if the user only briefly activates or touches the actuation field, the transmitted information does not change as a result, the same periodic signal is applied to the antenna system during actuation. Even via a chip, the signal can be changed regardless of the duration of the actuation of the operating field. With a static signal so only a rather simple information can be transmitted. However, this has the advantage that a chip does not necessarily have to be used to comply with a particular radio protocol, but it is sufficient if the printed circuit of the product generates a signal that is sent by the antenna system of the product and that of the user's mobile device is detected or decoded due to existing hardware and / or software there for the radio transmission.

An embodiment of the invention is that the electronic circuit comprises at least one printed oscillating circuit which is part of the antenna system for forming the signal applied to the antenna system. Then, by pressing an operating field, the signal of the resonant circuit can be changed. In the simplest case, the antenna system is formed only by the resonant circuit.

For example, it may be provided that the resonant frequency of the resonant circuit is variable by the actuation of an operating field. At the

Actuation of the operating field, the resonant circuit, for example, added an additional capacity, which just changed the resonant frequency.

It is also conceivable that the amplitude of the signal of the resonant circuit can be changed by actuating an operating field. That is, the fundamental frequency of the resonant circuit remains the same or approximately equal, only the amplitude undergoes a periodic change.

This can be achieved by assigning at least one actuating element to a further printed oscillating circuit of the electronic circuit, the further oscillating circuit having a further resonant frequency in order to produce a beat in the actuated state of the actuating element in the signal resulting from the two oscillatory circuits. If two signals are superimposed with a very similar frequency, then it is known to a beat, so a signal with average fundamental frequency, based on the two different fundamental frequencies of the respective resonant circuit, with a periodic change in the amplitude of the resulting signal.

In a particularly simple embodiment of the invention can be provided that the antenna system as part of the electronic circuit, namely as a printed transmission antenna is formed.

In addition, it may also be provided that the electronic circuit is connected to a microchip located on the product, for controlling the communication with a mobile electronic device in the near field. For example, when printing the electronic circuit, the corresponding connections can be printed for the microchip. The microchip can then have the following tasks:

Recording of energy from the radiated field of the reader of the mobile electronic device

Decoding the signal received by the reader

Query of the fields of action Return of information about the antenna system according to the given rules

Execution of actions based on the information received from the mobile electronic device, such as operating an LED with an intact communication connection with the mobile electronic device.

The power for the printed circuit for generating the first, second and any further signals may be sourced from a battery on the product or from a radio signal of the user's mobile electronic device, e.g. an NFC signal. In the first case, the battery can either be a concrete component or also printed.

The technically simplest and most cost-effective solution according to the invention, however, is to use as few concrete, that is not printed, components. Thus, it is best to print all the components of the circuit, which can be printed in known manner, at least the following circuit elements: electrical lines (tracks), coils, resistors, capacitors, diodes, transistors, batteries, actuators (such as switches), controls.

The starting material or the finished product, such as the packaging or the flyer are used according to the invention as a mechanical support for the printed electronic elements, but can also serve as an insulating layer in part.

Some of the circuit elements to be printed may have several different layers and therefore need to be manufactured in several successive printing steps. Functionally, a distinction is made between conductive layers (conductor layers), electrically insulating layers (insulating layers), such as dielectric layers, and semiconductor layers.

If individual circuit elements or components of the subject invention can not be printed, then they must be applied in adapted Pick & Place steps as known in printed circuit board manufacturing.

The printing methods used are those already known in connection with printed electronic circuits. Preferably additive processes are used in the production of the individual layers, and no subtractive methods, such as photolithography. The manufacturing process is simplified if several, preferably all, layers needed for the associated circuit elements are printed using the same printing process, such as

Screen printing to be produced. In that case only one printing device is necessary, which only has to be charged with different materials.

Typical layer thicknesses of a conductor layer begin at 0.5 μηι and can reach up to several 100 μηι rich. Depending on the printing method, the printed conductors can be only a few μm wide; typical widths are between 50 and 400 μm. There are no limits to the width.

The term printed electronic circuit refers to electronic components, assemblies, and applications that are made wholly or partially by printing. Instead of the printing inks, electronic functional materials which are in liquid or pasty form are printed. Often these are organic materials. A considerable reduction in manufacturing costs, the ability to print on large-area and flexible substrates, as well as novel functionalities open up fields of application for electronics that were previously or only partially accessible to conventional (inorganic) electronics.

An essential characteristic of printed electronics is the use of flexible substrates which enable the production of mechanically flexible electronic applications. When it comes to plastic films, polyethylene terephthalate (PET) film is often used because of its cost advantage and material properties, and sometimes polyethylene naphthalate (PEN) and polyimide (PI) film because of its higher temperature stability.

As the printing method for the subject invention, in particular, the following methods are used: screen printing, flexographic printing, gravure printing, offset printing, ink jet printing or stencil printing. These can also be combined with each other. The printing processes are known to the person skilled in the art and are not reproduced here.

Suitable conductive materials for the conductor layers are silver conductive paste.

Carbon paste, other modified metal particles (e.g., silvered copper particles), conductive polymers, or mixtures thereof. As conductive polymers, poly-3,4-ethylenedioxythiophene doped with polystyrene sulfonate (PEDOT: PSS) and polyaniline (PANI) can be used. Both polymers are commercially available in various formulations and have already been printed in inkjet, screen and offset printing or in screen, flexographic and gravure printing. Alternatively, silver nanoparticles in flexo, offset and inkjet printing, in the latter method, gold particles used. However, it is also possible to use other conductive materials as nanoparticles. In addition to the polymeric and metallic materials, the focus is also on carbon as a robust and cost-effective material for printed electronic applications.

Printable organic (e.g., various polymers) and inorganic insulators for the insulating layer exist in large numbers and can be processed in the various printing methods.

So that the circuit elements are not impaired in their function by external influences, it can be provided that the circuit elements are at least partially printed with an insulating material. As a result, these elements are at least, as far as the electrical conductivity is concerned, shielded from the environment by this insulating layer. The insulation material may also provide mechanical protection, such as from scratches or other wear of the elements.

The method for communication, that is to say for information transmission, with a product according to the invention comprises the steps of physically actuating a first printed actuating field on the product, of transmitting a first signal to the antenna system by the actuation of the first actuating field and interrogating it by radio from a mobile electronic device , the first signal is received and decoded by the mobile electronic device, and the mobile electronic device performs a first action based on this first signal.

Decoding has the meaning here that the instruction for the execution of the (first) action is assigned to the (first) signal received by the product by the mobile electronic device.

The method may also include physically actuating a second printed actuation field on the product (before or after the actuation of the first actuation field; if both are actuated simultaneously, either no meaningful signal is produced, or another signal will result, another action is assigned), by the actuation of the second actuation field, a second signal to the antenna system passes, the second signal is received and decoded by the same mobile electronic device, and the mobile electronic device based on this second signal performs a second action, which differs from the first Action is different.

Further, a sequence or order of operations of various operation fields may be decoded by the mobile device, and correspondingly different actions may be performed. Accordingly, it can be provided that at least one second printed actuating field is physically actuated on the product after the first actuating field, a second signal reaches the antenna system through actuation of the second actuating field, the second signal is received and decoded by the same mobile electronic device, and the mobile electronic device based on the order of the signals performs a further action, which is different from an action, triggered by the actuation of only the first actuation field, and an action, triggered by actuating only the second actuation field differs. Of course, the same actuation fields can be actuated several times in such a sequence of signals in order to produce a further action, for example by pressing the first, the second and then again the first actuation field.

The actuation field can be physically actuated by e.g. is touched with a finger.

The first and / or second and / or further action may include one of the following actions:

Downloading information from the Internet or from other external networks relating to information printed on the product to the mobile electronic device,

Displaying downloaded information on the mobile electronic device, ordering a commodity to which the information printed on the product relates.

The action performed by the mobile electronic device is usually receive or request no further information from the product after receipt of the corresponding first, second, further signal (because with the simplest embodiment of the product according to the invention - without microchip - such information is not present), but to resort to other data and information sources, eg create a connection to an internet site where an order can be placed. The action taken by the mobile electronic device is therefore preferably made without involving the product.

If the NFC technology is used, it can be provided that the signal of the antenna system of the product is transmitted according to the NFC protocol and decoded by means of an NFC reader of the mobile electronic device. It is also conceivable that the decoding takes place outside of standard NFC technology protocols.

In one embodiment, the signal may be transmitted by means of a microchip connected to the electronic circuit of the product. A simpler embodiment, however, provides for the generation of signals - in particular only - with printed elements and a printed antenna system.

To save a power supply unit on the product, it can be provided that the printed circuit is powered by the mobile electronic device with energy. BRIEF DESCRIPTION OF THE FIGURES The invention will be explained by way of example with reference to the following figures. Show it

1 is a schematic representation of a printed electronic circuit according to the invention with printed transmitting antenna,

2 shows a schematic representation of a printed electronic circuit according to the invention with transmitting antenna and NFC chip,

Fig. 3 is a schematic representation of a product according to the invention in communication with a mobile electronic device.

WAYS FOR CARRYING OUT THE INVENTION

In the manufacture of a product according to the invention, a first, e.g. belt-shaped starting material, such as paper for an advertising booklet, printed with information, e.g. with text and pictures concerning the advertised goods. Then, the individual layers of the circuit elements of the printed electronic circuit, e.g. roll-to-roll, printed on at least one side of the paper. As a rule, different numbers of printing steps are required for the individual circuit elements, e.g. each with a thickness of 1 to 100 pm. In this case, layers of different circuit elements can be printed in the same printing step.

To make it clear to the user what the operating fields are for, here - e.g. In the printing step for the information - a note to be printed, such as "Please bring your smartphone close to the brochure and press here if you want to order the goods displayed." Another field of activity could be labeled with "Please bring your smartphone close to the brochure and Click here, if you want to remember the displayed goods. "

In Fig. 1, the finished printed circuit is shown. This includes an operating field S, intended to be touched or pressed with the human finger. It is also within the scope of the invention, the operating field S to be designed so that it can also be operated differently, for example, touched with a tip of an object or can be pressed.

The actuation field S may comprise a switch closing a circuit, e.g. a capacitive switch or a contact switch. As long as this circuit is closed, the signal applied to the likewise printed transmission antenna I is changed: Each actuation field S closes its own circuit of the printed circuit, which in this example switches on a capacitor C2. The resonant circuit when the switch is not closed has a resonant frequency, which is determined by the capacitance C1. If the switch of the operating field S is closed, this frequency changes.

Fig. 2 describes a circuit with a chip CH to which an operating field S is connected. This may again be a switch or another actuator. If the switch is open, the chip CH returns a predetermined signal. When the switch is closed, the chip CH returns another signal via the transmitting antenna I of the antenna system. The first and second signals are detected by the mobile device and the corresponding actions are performed.

Fig. 3 describes a system with an operating field S, which can be implemented with (see FIG. 2) or without a chip (see FIG. 1), inasmuch as between the operating field S and transmitting antenna I a black box is drawn, and with one, a Transmitting antenna I comprehensive antenna system that communicates with a mobile device M.

The first, second or further signal which is triggered on the basis of the first, second or further field of action, however, can also only cause, for example, further information about the product displayed on the product (here promotional brochure), from data sources other than the product (eg from the Internet) are downloaded to the mobile device 8.

By using an NFC chip and the complex logic that is available with it, complex information can also be stored in the product and transmitted to the reader via the antenna system, e.g. an internet address. This is then called by the standard NFC software alone. If no chip is available in the product, software must be installed on the mobile reader, e.g. calls an internet address. A chip also takes over the reading of the fields of operation and their assignment and only transmits the information about the actuated fields to the mobile reader.

Instead of the NFC technology, other RFID technologies can also be used; in particular, the product according to the invention can be passive, that is to say operated without its own power supply and react only to an RFID signal of a corresponding transmitter of a mobile device M. Again, the printed circuit can simply have only a corresponding printed antenna system that can respond to an RFID signal. Or it may be a separate RFID tag or a separate RFID chip adhered to the printed circuit or otherwise conductively connected thereto.

Also, Bluetooth can be used instead of NFC or other RFID technologies, in which case a corresponding chip must be provided on the product here in order to handle the communication regarding authorization of a Bluetooth connection. The advantage of using NFC or Bluetooth technology is that newer smartphones already have readers for both technologies.

Claims (19)

1. A product made of, preferably flat, starting material, in particular of paper, cardboard, cardboard or plastic film, the product being printed in particular with information, the product having at least one printed electronic circuit, and wherein the product comprises at least one antenna system for the has radio communication with a mobile electronic device (M) in the near field, characterized in that the electronic circuit has at least a first printed operating field (S), wherein in the actuated state of the first operating field (S) at the antenna system, a first signal is applied differs from a signal at the antenna system when the operation field (S) is not operated. 2. Product according to claim 1, characterized in that the electronic circuit has at least a second printed actuating field, so that upon actuation of the second operating field on the antenna system, a second signal is applied, which differs from the first signal. 3. Product according to claim 1 or 2, characterized in that the actuating field (S) has a printed switch, which is in the actuated state of the actuating field in the closed state. 4. Product according to one of the preceding claims, characterized in that the first or optionally further signal of the actuating field is a static signal. 5. Product according to one of the preceding claims, characterized in that the electronic circuit comprises at least one printed oscillating circuit, which is part of the antenna system for forming the signal applied to the antenna system. 6. Product according to claim 5, characterized in that the resonant frequency of the resonant circuit by the actuation of an actuating field (S) is variable. 7. Product according to claim 5, characterized in that the amplitude of the signal of the resonant circuit by the actuation of an actuating field (S) is variable. 8. Product according to claim 7, characterized in that at least one actuating element (S) is associated with another printed circuit of the electronic circuit, wherein the further resonant circuit has a further resonant frequency to produce a beat in the actuated state of the actuating element in the two Oscillating circuits resulting signal. 9. Product according to one of the preceding claims, characterized in that the antenna system is formed as part of the electronic circuit, namely as a printed transmission antenna (I). 10. Product according to one of claims 1 to 9, characterized in that the electronic circuit is connected to a product located on the microchip (CH), for controlling the communication with a mobile electronic device (M) in the near field. 11. A method for transmitting information with a product according to one of claims 1 to 10, characterized in that on the product a first printed operating field (S) is physically actuated, passes through the actuation of the first operating field, a first signal to the antenna system and via radio from a mobile electronic device (M), the first signal from the mobile electronic device (M) is received and decoded, and the mobile electronic device (M) based on this first signal performs a first action. 12. The method according to claim 11, characterized in that a second printed actuating field is physically actuated on the product, a second signal arrives at the antenna system by actuation of the second actuating field, the second signal is received and decoded by the same mobile electronic device (M), and the mobile electronic device (M) executes a second action different from the first action based on this second signal. 13. The method according to claim 11, characterized in that the product after the first operating field (S) at least a second printed actuating field is physically actuated, passes through the actuation of the second operating field, a second signal to the antenna system, the second signal from the same mobile electronic device (M) is received and decoded, and the mobile electronic device (M) based on the order of the signals performs another action, which is triggered by an action, triggered by pressing only the first operation field (S), and by an action from operating only the second operating field, different. 14. The method according to any one of claims 11 to 13, characterized in that the actuating field (S) is physically actuated by being touched with a finger. 15. The method according to any one of claims 11 to 14, characterized in that the first and / or optionally second and / or optionally further action comprises one of the following actions: Downloading information from the Internet or from other external networks, based on am Product printed information refers to the mobile electronic device (M), displaying downloaded information on the mobile electronic device (M), ordering a product to which the information printed on the product relates. 16. The method according to any one of claims 11 to 15, characterized in that the performed by the mobile electronic device (M) action takes place without involving the product. 17. The method according to any one of claims 11 to 16, characterized in that the signal of the antenna system of the product according to the NFC protocol is transmitted and decoded by means of an NFC reader of the mobile electronic device (M). 18. The method according to any one of claims 11 to 17, characterized in that the signal is transmitted by means of a microchip (CH), which is connected to the electronic circuit of the product. 19. The method according to any one of claims 11 to 18, characterized in that the printed circuit is powered by the mobile electronic device (M) with energy.