Patent Description:
In organic electrochromic displays, a persistent change of color in an organic electrochromic material is obtained in response to an electrical stimulus. A layer of electrolyte is sandwiched between the electrochromic material and a counter electrode. Upon applying a voltage between the electrochromic layer and the counter electrode, the electrochromic layer switches between an oxidized and a reduced state, resulting in a change of color in the electrochromic material. Organic electrochromic displays are low-powered and can be printed on a flexible substrate, making possible a wide range of applications, including smart labels, medical devices, and sensor panels. Such an organic electrochromic display is disclosed in <CIT>.

In many applications, an interface with the user is provided by membrane switches. These are cost-effective and provide some benefits such as being sealed, giving potential resistance to elements and ease of cleaning, for example. However, membrane switches rely on a mechanical displacement to bring two conducting surfaces in contact and are therefore prone to wear. Adding touch sensing capability to an electrochromic display would remove the mechanical wear, thus providing a more reliable device. In addition, using the display itself as a touch sensor would allow for a wider range of interaction between a user and the device.

An electrochromic display device with touch functionality is disclosed in <CIT>. An electrochromic mirror with a capacitive touch sensor is disclosed in <CIT>. And a liquid crystal display with touch detection function is disclosed in <CIT>.

In light of the above, there is a need for a simple device combining an electrochromic display with a touch sensing capability. It is an object of the present disclosure to provide such a device.

The invention is defined by the appended independent claim, with embodiments being set forth in the appended dependent claims, in the following description, and in the drawings.

According to an aspect of the inventive concept, there is provided an electrochromic display device comprising a set of pixel cells, each pixel cell being arranged to display at least one symbol, which at least one symbol is repeatedly switchable between an on-state and an off-state or between two different visually detectable colouring states. The on-state and the off-state have two different visually detectable colouring states, Each pixel cell comprises:.

said counter electrodes of said set of pixel cells are electrically separated from each other.

The device further comprises a circuitry in electronic contact with each connector in said pair of connectors of each pixel cell of said set of pixel cells, which circuitry is configured to be connected to a power supply, and which circuitry is further configured to selectively provide a respective potential difference between said pair of connectors of each pixel cell in said set of pixel cells at least when connected to said power supply.

Said circuitry is further configured to detect a change in capacitance in at least one pixel cell of said set of pixel cells, said change in capacitance being caused by an external object in close proximity to said at least one pixel cell, and switch a subset of pixel cells of said set of pixel cells between one of said on-state and said off-state, and the other of said on-state and said off-state, in response to said change in capacitance exceeding a predetermined threshold, by providing said respective potential difference between each one of said pair of connectors of said subset of pixel cells. In other words, in response to said change in capacitance exceeding a predetermined threshold, the circuitry is configured to switch a subset of pixel cells of said set of pixel cells between said on-state and said off-state, or vice-versa. Consequently, in response to said change in capacitance exceeding a predetermined threshold, the circuitry is configured to switch a subset of pixel cells of said set of pixel cells between said on-state and said off-state, or between said off-state and said on-state.

The present disclosure is at least partially based on the realization that the manufacturing time and/or cost can be lowered if the first layer and counter electrode layer/counter electrode/counter electrodes are used for detecting a user interaction. Compared to a device in which one or more devices and/or dedicated layer is necessary for detecting user interaction, a device according to the present invention can be manufactured using fewer processing steps.

In essence, the invention provides a display that can be controlled by an external object, such as a finger of a user, a stylus pen for touch screens, or any other conductive object.

According to one embodiment, said circuitry is configured to detect said change in capacitance in said at least one pixel cell via at least one of said pair of connectors of said set of pixel cells.

A portion of each connector in said pair of connectors may be in direct contact with a respective one of said first layer and said counter electrode.

According to one example said change in capacitance is detected by continuously or intermittent monitoring or measuring the potential of only one of said connectors in said pair of connectors, or a property corresponding to the potential of only one of said connectors in said pair of connectors. According to an alternative example said change in capacitance is detected by continuously or intermittent monitoring or measuring the respective potential of both of said connectors in said pair of connectors, or a property corresponding to the respective potential of both of said connectors in said pair of connectors, such as the potential difference between said pair of connectors.

Said change in capacitance may be detected by continuously or intermittent monitoring or measuring the potential of only one of said first layer and said counter electrode of at least one pixel, or a property corresponding to the potential and/or capacitance of only one of said first layer and said counter electrode of at least one pixel. According to an alternative example said change in capacitance is detected by continuously or intermittent monitoring or measuring the respective potential of both said first layer and said counter electrode of at least one pixel, or a property corresponding to the respective potential and/or capacitance of both of said first layer and said counter electrode of at least one pixel, such as the potential difference or capacitance between first layer and said counter electrode.

According to one embodiment, said subset of pixel cells may consist of a single pixel cell. In one example configuration, a change in capacitance may be detected in one pixel cell, in response to which said one pixel cell is switched between said off-state and said on-state (or vice versa). Alternatively, a change in capacitance may be detected in a first pixel cell, in response to which a second pixel cell is switched between said off-state and said on-state, which second pixel cell is different from said first pixel cell.

According to one embodiment, said subset of pixel cells may comprise a plurality of pixel cells, such as two, three or more pixel cells. In such a configuration, a plurality of pixel cells may be switched between said off-state and said on-state in response to detecting said change in capacitance. The plurality of pixel cells may comprise the at least one pixel cell in which the change in capacitance is detected. Alternatively, the plurality of pixel cells may comprise only pixel cells in which a change in capacitance is not detected.

A wide range of different interactions is thus possible, from a simple switch of a pixel cell in response to a touch, to complex rule-based interactions. It should be noted that a change in capacitance detected in a particular pixel cell may result in different subsets of pixel cells being switched, depending on the current state of each pixel cell in the set of pixel cells.

According to one embodiment, said set of pixel cells comprises a plurality of pixel cells, which plurality of pixel cells is divided or grouped into at least a first group of pixel cells and optionally a second group of pixel cells. Each first layer in said first group of pixel cells forms a respective portion of a respective continuous layer, which respective continuous layer extends between at least two neighboring pixel cells in said first group of pixel cells. Said connector in electronic contact with said first layer of said pixel cells of said first group of pixel cells is optionally one and the same for said at least two neighboring pixel cells between which said respective continuous layer extends.

The respective first layers of the pixel cells of said second group are electrically separated from each other. Each said connector in electronic contact with said first layer of the pixel cells of said second group is a separate connector.

In this configuration, the at least two neighboring pixel cells in said first group of pixel cells act as one capacitive touch sensor. The pixel cells can thus be grouped into different touch areas. A change in capacitance may be detected anywhere in the at least two neighboring pixel cells. Each of the at least two neighboring pixel cells is however independently switchable between the on-state and the off-state.

According to one embodiment, said first group of pixel cells comprises all pixel cells in said plurality of pixel cells, and all of the first layers in said first group of pixel cells form a respective portion of the same continuous layer, which continuous layer continuously extends between all pixel cells in said plurality of pixel cells. Said connector in electronic contact with said first layer is preferably one and the same for all pixel cells in said plurality of pixel cells.

This provides a device with fewer connectors, thus minimizing a number of electric conductors needed to connect said circuitry with said connectors. It allows for configurations in which a response may be triggered indifferently by a change in capacitance in any one of the pixel cells of the plurality of pixel cells, but each pixel cell of the plurality of pixel cells is independently switchable between the on-state and the off-state.

According to one embodiment, said set of pixel cells comprises a plurality of pixel cells, and the respective first layers of said plurality of pixel cells are electrically separated from each other. Each said connector in electronic contact with said first layer of each pixel cell is a separate connector.

In this configuration, each one of said plurality of pixel cells is directly and individually addressable both in terms of detecting a change of capacitance in each pixel cell and in terms of switching each pixel cell between the on-state and the off-state.

According to one embodiment, for each pixel cell of said set of pixel cells, a first terminal and a second terminal of said circuitry are electronically connected to one connector of said pair of connectors of said pixel cell, said first terminal being connected to said one connector via a resistor. Said circuitry is configured to execute the following steps:.

Said change in capacitance exceeding a predetermined threshold is detected or determined based on said elapsed time T exceeding a predetermined time threshold.

In relation to this disclosure, the term "provide" a potential comprises applying the potential, at this instant, or having previously applied and since then maintained said potential. In other words, in step (a), at a first instance in time t<NUM>, the potential at said second terminal is the first potential and the potential at said first terminal is the second potential. It does not exclude that the first and/or the second potential was/were applied to said second and/or first terminal before said first instance in time t<NUM>.

When the electrochromic display device is in a sense mode, the circuitry may be configured to execute the steps (a) to (c) repeatedly, at a chosen frequency. This allows the circuitry to monitor the capacitance of each pixel cell.

According to a general example, the measured time corresponds to the time constant of an RC circuit formed by the connection between the circuitry, the resistor, and the pixel cell acting as a capacitor. An external object, such as a user's finger, in close proximity of the pixel cell, forms a combined capacitor with the pixel cell, increasing its capacitance. The time constant of the RC circuit, i.e. the time required to charge (or discharge) the capacitor thus increases.

The change in capacitance is determined to exceed said predetermined threshold, indicating that said change in capacitance in said pixel cell is caused by an external object in close proximity to said pixel cell, e.g. based on a difference between said determined elapsed time T and a baseline interval exceeding a predetermined time difference. The baseline interval corresponds to small changes in capacitance.

Additionally, this configuration allows the sensitivity of the touch sensor to be adjusted by choosing an appropriate resistance value of the resistor. As an example, a resistor in the range of <NUM> kOhm to <NUM> MOhm may be used. A higher resistance provides higher sensitivity (i.e. a change in capacitance is detected at a greater distance between e.g. a finger and the pixel cell) but a slower response time.

According to one embodiment, said circuitry is further configured to process said determined time, for each pixel cell of said set of pixel cells, and to determine, based on said processed determined time, whether a change in capacitance in a pixel cell exceeds said predetermined threshold.

The measured time may be processed by applying a filter to the measured time data in order to reduce the effect of disturbances. As an example, the filter may consist in calculating an exponential moving average of a derivative of the measured time. The resulting processed measured time may provide more reliable data for correctly identifying a change in capacitance resulting from a touch (or object such as a finger in close proximity to) in a pixel cell.

According to one embodiment, the one connector of said pair of connectors of said pixel cell is the connector in electronic contact with the first layer of said pixel cell.

According to one embodiment, the one connector of said pair of connectors of said pixel cell is the connector in electronic contact with the counter electrode of said pixel cell.

Thus, different options for connecting the circuitry to said pixel cell are possible, allowing the most appropriate connection to be chosen according to the layout of the pixel cell. For example, depending on the shape of the first layer and of the counter electrode layer/counter electrode of said pixel cell, a connection to one or the other layer may minimize the number of conductors crossing the different layers. This reduces the potential sources of disturbance and provides for more reliable sensing.

According to one embodiment, each respective one connector of at least two pixel cells are all connected to a common first terminal and a respective separate second terminal of said circuitry.

This configuration decreases the number of pins needed in said circuitry. Additionally, fewer conductors are needed to connect the pixel cells to the circuitry, thus reducing the potential sources of disturbances.

According to one embodiment, said circuitry comprises one of a microcontroller and a Field Programmable Gate Array (FPGA). Additionally or alternatively, the circuitry comprises a circuit adapted to apply a potential, measure a potential, and measure time. The choice of circuitry can for example be adapted to the layout of the device, the number of pixel cells and the complexity of the intended interaction between a user and the device.

According to one embodiment, said power supply comprises one of a battery, a solar cell, a supercapacitor, a USB-connection from another device, a wall socket. An appropriate power supply can thus be chosen depending on the expected power consumption of the device, whether the device needs to be portable, how long time the device needs to be able to operate.

According to one embodiment, said first layer comprises a material selected from a group comprising: Poly(<NUM>,<NUM>-ethylenedioxythiophene) doped with poly(styrenesulfonic acid) (PEDOT:PSS), polythiophenes, polyaniline, polypyrrole, and PEDOT deposited through vapor phase polymerization on a pre-deposited oxidant, and/or a combination thereof.

According to one embodiment, said counter electrode layer or counter electrode comprises a material selected from a group comprising: PEDOT:PSS and carbon.

According to one embodiment, said pair of connectors comprises a material selected from a group comprising: silver, PEDOT:PSS, and carbon.

Further, the "first" layer in relation to this invention is an electrochromic layer composed of one material or a combination of materials. The material(s) may be organic or inorganic, molecular or polymeric. Such an electrochromic layer, independent of whether it is composed of one material or is an ensemble of more than one material, combines the following properties: at least one material is electrically conducting in at least one oxidation state, and at least one material is electrochromic, i.e. exhibits colour change as a result of electrochemical redox reactions within the material, such as e.g. a reduction reaction in the electrochromic layer.

The electrochromic display device may comprise, as electrochromic material and/or electrochemically active material, a polymer which is electrically conducting in at least one oxidation state, and optionally also comprises a polyanion compound.

Electrochromic polymers for use in the electrochromic display device of the invention are for example selected from the group consisting of electrochromic polythiophenes, electrochromic polypyrroles, electrochromic polyanilines, electrochromic polyisothianaphthalenes, electrochromic polyphenylene vinylenes and copolymers thereof. In an embodiment, the electrochromic polymer is a homopolymer or copolymer of a <NUM>,<NUM>-dialkoxythiophene, in which said two alkoxy groups may be the same or different or together represent an optionally substituted oxy-alkylene-oxy bridge. In yet an embodiment, the electrochromic polymer is a homopolymer or copolymer of a <NUM>,<NUM>-dialkoxythiophene selected from the group consisting of poly(<NUM>,<NUM>-methylenedioxythiophene), poly(<NUM>,<NUM>-methylenedioxythiophene) derivatives, poly(<NUM>,<NUM>-ethylenedioxythiophene), poly(<NUM>,<NUM>-ethylenedioxythiophene) derivatives, poly(<NUM>,<NUM>-propylenedioxythiophene), poly(<NUM>,<NUM>-propylenedioxythiophene) derivatives, poly(<NUM>,<NUM>- butylenedioxythiophene), poly(<NUM>,<NUM>-butylenedioxythiophene) derivatives, and copolymers therewith. The polyanion compound is then preferably poly(styrene sulfonate).

As is readily appreciated by the skilled man, in alternative embodiments of the invention, the electrochromic material comprises any non-polymer material, combination of different non-polymer materials, or combination of polymer materials with non-polymer materials, which exhibit conductivity in at least one oxidation state as well as electrochromic behaviour. For example, one could use a composite of an electrically conducting material and an electrochromic material, such as electrically conductive particles such as tin oxide, ITO or ATO particles with polymer or non-polymer electrochromic materials such as polyaniline, polypyrrole, polythiophene, nickel oxide, polyvinylferrocene, polyviologen, tungsten oxide, iridium oxide, molybdenum oxide and Prussian blue (ferric ferrocyanide). As non-limiting examples of electrochromic elements for use in the device of the invention, mention can be made of: a piece of PEDOT:PSS, being electrochromic as well as both electrically and ionically conducting; a piece of PEDOT:PSS with Fe2+ /SCN-, PEDOT:PSS being conducting and electrochromic as mentioned above and Fe2+ /SCN- being an additional electrochromic component (see below); a piece composed of a continuous network of conducting ITO particles in an insulating polymeric matrix, in direct electrical contact with an electrochromic WO3-coating; a piece composed of a continuous network of conducting ITO particles in an insulating polymeric matrix, in contact with an electrochromic component dissolved in an electrolyte. As described above, an electrochromic display device may comprise a further electrochromic material for realization of displays with more than one colour. This further electrochromic material can be provided within the electrochromic pixel element or the solidified electrolyte, which then for example comprises an electrochromic redox system, such as the redox pair of colourless Fe2+ and SCN-ions on one hand, and of red Fe3+ (SCN)(H2O)<NUM> complex on the other. By way of further, non-limiting example, such materials may be selected from different phenazines such as DMPA - <NUM>, <NUM>-dihydro-<NUM>,<NUM>-dimethylphenazine, DEPA - <NUM>, <NUM>-dihydro-<NUM>,<NUM>-diethylphenazine and DOPA - <NUM>, <NUM>-dihydro-<NUM>,<NUM>-dioctylphenazine, from TMPD - N,N,N',N'-tetramethylphenylenediamine, TMBZ - N,N,N',N'-tetramethylbenzidine, TTF - tetrathiafulvalene, phenanthroline-iron complexes, erioglaucin A, diphenylamines, pethoxychrysoidine, methylene blue, different indigos and phenosafranines, as well as mixtures thereof.

The electrodes, counter electrodes and/or the pair of connectors may comprise any electron conducting material, such as electrically conducting polymers, metal, conducting carbon, titanium, platinum, graphite, graphene, noble metals and inert metals or combinations of such electron conductive materials. The electrodes may further comprise electrochemically inert metals such as gold or other conducting materials suitable for being in contact with electrochemically active layers. Normally, conducting material suitable for being in contact with electrochemically active layers is inert such that they do not give rise to substantial electrochemical reactions. These materials may e.g. be provided as an ink or paste which is arranged on an insulating film during a manufacturing, or pre-manufacturing process.

The pair of connectors may alternatively or additionally comprise silver.

A more complete discussion of possible materials and processing steps is provided in <CIT> on pages <NUM>-<NUM>.

Direct electrical contact: Direct physical contact (common interface) between two phases (for example between electrochemically active organic material and electrolyte) that allows for the exchange of charges through the interface. Charge exchange through the interface can comprise transfer of electrons between electrically conducting phases, transfer of ions between ionically conducting phases, or conversion between electronic current and ionic current by means of electrochemistry at an interface between for example counter element and electrolyte or electrolyte and electrochromic element, or by occurrence of capacitive currents due to the charging of the Helmholtz layer at such an interface.

Ionic contact between two elements is provided by at least one material capable of transporting ions between the two elements. An electrolyte, in direct contact (common interface) with a first and a second electrochemically active layer, is one example of a material which may provide ionic contact between the two electrochemically active layers. The electrolyte may hence be referred to as being in ionic contact with the two electrochemically active layers.

Two materials may be in electronic contact with each other, e.g. via a third material. Electronic contact between two elements is provided by at least one material capable of transporting electrons between the two elements. A layer of carbon, in direct contact (common interface) with a first and a second electrochemically active layer, is one example of a material which may provide electronic contact between the two layers. The layer of carbon may hence be referred to as an electronic conductor, or electronically conductive.

Direct physical contact: Common interface between two materials or layers.

The inventive concept, some non-limiting embodiments and further advantages will now be further described with reference to the drawings, in which:.

<FIG> is schematic illustration, in exploded view, of the different layers comprised in a pixel cell of one example embodiment of the electrochromic display device. A transparent substrate (not shown in <FIG>) is first provided. In order of printing, the following layers are then arranged on the substrate:.

The electrochromic material of the first layer <NUM> is preferably PEDOT:PSS. Alternatively, the first layer <NUM> may for example comprise polythiophenes, polyaniline, polypyrrole, or PEDOT deposited through vapor phase polymerization on a pre-deposited oxidant.

The symbol defining layer <NUM>, which is electronically and ionically insulating, is arranged in direct contact with the first layer <NUM>. The symbol defining layer comprises openings <NUM>, <NUM>, <NUM>, <NUM>, <NUM> defining the shape of symbols that are to be displayed. Here, each symbol takes the shape of a number from "<NUM>" to "<NUM>". An additional opening <NUM> is provided for facilitating electronic contact with the first layer <NUM>.

The electrolyte layer <NUM> comprises five portions <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, each portion completely filling a respective opening <NUM>, <NUM>, <NUM>, <NUM>, <NUM> of the symbol defining layer <NUM>, such that each portion is in ionic contact with the first layer <NUM> underneath. The five portions <NUM>, <NUM>, <NUM>, <NUM>, <NUM> of the electrolyte layer <NUM> are ionically isolated from each other.

As seen in <FIG>. each counter electrode <NUM>, <NUM>, <NUM>, <NUM>, <NUM> may form a respective portion of a counter electrode layer <NUM>, which counter electrode layer is discontinuous as the counter electrodes are electrically separated from each other.

The counter electrode layer <NUM> comprises five counter electrodes <NUM>, <NUM>, <NUM>, <NUM>, <NUM> arranged on top of and covering a respective portion <NUM>, <NUM>, <NUM>, <NUM>, <NUM> of the electrolyte layer <NUM>. Here, each counter electrode <NUM>, <NUM>, <NUM>, <NUM>, <NUM> is provided with an elongated portion extending beyond or outside the respective portions of the electrolyte layer <NUM>. An additional electrode referred to as the pixel electrode <NUM> is printed as part of the counter electrode layer <NUM>. The pixel electrode is aligned with the additional opening <NUM> of the symbol defining layer <NUM>, such that the pixel electrode is in electronic contact with the first layer <NUM>.

An optional silver pattern layer <NUM> is printed on top of the counter electrode layer <NUM>. The silver pattern <NUM> facilitates electronic contact between the counter electrode layer <NUM> and the circuitry (not shown in <FIG>) used to control the electrochromic display device. The silver pattern layer <NUM> comprises a pair of connectors <NUM>, <NUM>. The first connector <NUM> is connected to a silver wire <NUM> aligned with the pixel electrode <NUM> of the counter electrode layer <NUM>. The circuitry, when connected to the first connector <NUM>, is thus in electronic contact with the first layer <NUM> via the pixel electrode <NUM>. The second connector <NUM> is connected to five silver wires <NUM>, <NUM>, <NUM>, <NUM>, <NUM> each aligned with the elongated portion of a respective counter electrode <NUM>, <NUM>, <NUM>, <NUM>, <NUM>. The circuitry, when connected to the second connector <NUM>, is thus in electrical contact with each of the five portions <NUM>, <NUM>, <NUM>, <NUM>, <NUM> of the electrolyte layer <NUM> via the respective counter electrodes.

In an alternative, a separate connector could be provided for each counter electrode <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, instead of a common connector <NUM>. The circuitry could then be connected to each separate connector to provide electrical contact with each of the five portions <NUM>, <NUM>, <NUM>, <NUM>, <NUM> of the electrolyte layer <NUM> via the respective counter electrodes.

An electrochromic display device comprising a pixel cell as illustrated in <FIG> operates by applying an electric potential difference across the electrolyte layer <NUM>. A first potential is applied to the first layer <NUM>, via the first connector <NUM>, and a second potential is applied to the counter electrode layer <NUM>, via the second connector <NUM>. The difference in potential creates an electric field in the electrolyte layer <NUM>, which initiates a reduction or oxidation of a portion of the first layer <NUM> in contact with the electrolyte layer <NUM>. In turn, this causes a color change of the portion of the first layer <NUM>. Depending on the oxidized or reduced state of the first layer <NUM>, the symbols are in an off-state (no coloration, symbols not visible) or in an on-state (coloration, symbols visible).

As seen in <FIG> the first layer of each pixel cell is a respective portion of the continuous layer shown in <FIG> between the symbol defining layer and the eye.

The working principle of such an electrochromic display device is described in further detail in <CIT>. This arrangement of the different layers as outlined above also corresponds in principle to what is described in further details in <CIT>.

<FIG> shows two separate electrochromic displays ECD1, ECD2, each comprising the layers illustrated in <FIG>. Each display ECD1, ECD2 thus comprises one pixel cell with five symbols in the shape of the numbers "<NUM>" to "<NUM>". The pixel cell of the first display ECD1 is in the on-state, with the symbols colored and visible to an observer. In contrast, the pixel cell of the second display ECD2 is in the off-state. The outline of the symbols is shown on the second display ECD2 for illustrative purposes.

The respective connectors <NUM>, <NUM>, <NUM>', <NUM>' of each display are connected to a circuitry in the form of a microcontroller <NUM>. In this configuration, each pixel cell is connected to three different terminals of the microcontroller <NUM>. The connector <NUM> associated with the pixel electrode (not shown in <FIG>; corresponding to <NUM> in <FIG>) of the first display ECD1 is connected to terminal <NUM> of the microcontroller. This terminal can be referred to as the Common Pin for ECD <NUM>. The connector <NUM> associated with the counter electrodes (not shown in <FIG>; corresponding to <NUM>, <NUM>, <NUM>, <NUM>, <NUM> in <FIG>) is connected to terminals <NUM> and <NUM> of the microcontroller <NUM>, and between terminal <NUM> and connector <NUM> there is a resistor R1. Terminal <NUM> can be referred to as the Send Pin and terminal <NUM> can be referred to as the Receive Pin for ECD1.

The second display ECD2 is correspondingly connected to the microcontroller <NUM>, such that the first connector <NUM>' is connected to terminal <NUM> of the microcontroller <NUM>, and the second connector <NUM>' is connected to terminal <NUM> and terminal <NUM> of the microcontroller, and between terminal <NUM> and connector <NUM>' there is a resistor R2. Terminal <NUM> can be referred to as the Common Pin for ECD <NUM>, whereas terminals <NUM> and <NUM> can be referred to as the Receive Pin and the Send Pin for ECD2, respectively.

Alternative connections between the connectors <NUM>, <NUM>, <NUM>', <NUM>' of the pixel cells of the displays ECD1 and ECD2 and the microcontroller <NUM> are possible. For example, the connector <NUM>, <NUM>' corresponding to the pixel electrode may be connected to a Send Pin/Receive pair of pins of the microcontroller <NUM>, in which case the connector <NUM>, <NUM>' corresponding to the counter electrodes is connected to the Common Pin.

In another alternative, the Send pin is shared between the pixel cells of the two displays ECD1 and ECD2, meaning that the second connector <NUM>, <NUM>' of each pixel cell is connected, via a respective resistor R1, R2, to the same terminal of the microcontroller <NUM>. The respective second connector <NUM>, <NUM>' is connected to a respective Receive Pin of the microcontroller <NUM>. The first connector <NUM>, <NUM>' of each respective pixel cell is connected to a respective Common Pin of the microcontroller <NUM>. This configuration, sharing a Send Pin between several pixel cells, reduces the total number of terminals needed on the microcontroller <NUM> from 3N to 2N+<NUM>, where N is the number of pixel cells.

The shared Send Pin configuration may also alternatively be connected such that the respective first connectors <NUM>, <NUM>' is connected to the shared Send Pin and a respective Receive Pin, while the respective second connector <NUM>, <NUM>' is connected to a respective Common Pin of the microcontroller <NUM>.

It should be noted that the pixel cells of the two displays ECD1 and ECD2 could alternatively be printed on a common substrate, thus forming a single display with two pixel cells. In such a configuration, the same connection between the pixel cells and the microcontroller <NUM> as described above could be used.

In use, the capacitance in a pixel cell is measured, in arbitrary units, by calculating the time it takes for the Receive pin to go from a LOW state to a HIGH state. This is achieved e.g. according to an algorithm illustrated in the flow chart of <FIG>, in which the steps consist in:.

In read mode the microcontroller determines the electric potential at the pin as a HIGH state or LOW state depending on the size thereof.

If an external object, such as a human finger, is in close proximity to a pixel cell, the object forms a capacitor in combination with the layers of the pixel cell. In this condition, the time required to change the state of the Receive pin <NUM>, <NUM> from LOW to HIGH increases, resulting in a higher value of the capacitance variable returned. In practice, the algorithm described above is performed repeatedly, such that a signal consisting of successive values of the capacitance variable is obtained. A change in capacitance is thus determined when a difference in the time needed to change the state of the Receive pin <NUM>, <NUM> from LOW to HIGH exceeds a predetermined threshold.

An alternative algorithm, in which the time required to change the state of the Receive pin <NUM>, <NUM> from HIGH to LOW is measured, can be used to the same effect.

Depending on the actual configuration of the display device, the capacitance value signal may be affected by noise or disturbances. A potential source of disturbance is, for example, in a display comprising several pixel cells, conductors of the silver pattern layer overlapping different pixel cells. Switching one pixel cell between the off-state and the on-state can then affect the capacitance value signal of another pixel cell, even in the absence of a touch. Further, a finger in proximity to one pixel cell could potentially affect the capacitance value signal of another pixel cell having an associated conductor overlapping the former pixel cell. Care should therefore be taken when designing a display device to minimize such overlaps. The capacitance value signal can be also filtered in order to remove potential noise or disturbances and make the determination that a change in capacitance is e.g. due to an actual touch by a user more reliable. As a non-limiting example, the signal may be subjected to an Exponential Moving Average filter.

The sensitivity of the touch sensor formed by each pixel cell is also determined by the resistance of the respective resistor R1, R2. The appropriate choice of resistor may depend both on the desired sensitivity (e.g. distance at which a touch is registered) and on the specific microcontroller used. As an example, resistors of <NUM> MOhm have been used with an Arduino Mega2560 microcontroller and resistors of <NUM> kOhm have been used with an Arduino UNO microcontroller. Resistors in the range of <NUM> kOhm to <NUM> MOhm may be used. Depending on the application, the resistor may be a commercially available resistor, or the resistor may be printed when printing the display.

<FIG> show six layers of an electrochromic display comprising three pixel cells, one by one, according to the following print order:.

The first layer <NUM> shown in <FIG> comprises three physically separate electrochromic segments <NUM>, <NUM>, <NUM>. The symbol defining layer <NUM> (<FIG>) is arranged in direct contact with the first layer <NUM>. Three circular openings <NUM>, <NUM>, <NUM> are vertically aligned with a respective segment <NUM>, <NUM>, <NUM> of the first layer <NUM>, defining one circular symbol for each pixel cell of the device. Three small openings <NUM>, <NUM>, <NUM> are respectively arranged in proximity to the circular openings <NUM>, <NUM>, <NUM>, such that each small opening <NUM>, <NUM>, <NUM> is vertically aligned with the same segment <NUM>, <NUM>, <NUM> of the first layer <NUM> as the circular opening <NUM>, <NUM>, <NUM> in proximity to which it is arranged.

The third layer is the electrolyte layer <NUM> (<FIG>), which comprises three circular electrolyte islands <NUM>, <NUM>, <NUM>, corresponding to the circular shapes defined by the symbol defining layer <NUM>. Each electrolyte island <NUM>, <NUM>, <NUM> fills its respective corresponding opening <NUM>, <NUM>, <NUM> of the symbol defining layer completely.

<FIG> shows the counter electrode layer <NUM>, comprising three counter electrodes <NUM>, <NUM>, <NUM>, and three pixel electrodes <NUM>, <NUM>, <NUM>. The counter electrodes are aligned with the openings of the symbol defining layer <NUM> and the respective electrolyte islands <NUM>, <NUM>, <NUM>. Each counter electrode has a generally circular shape corresponding to the shape of the symbol, with a respective protruding connection point 4001a, 4002a, 4003a. The pixel electrodes <NUM>, <NUM>, <NUM> are aligned with the small openings <NUM>, <NUM>, <NUM> of the symbol defining layer <NUM>.

The insulating layer <NUM> (<FIG>) has openings <NUM>-<NUM> respectively aligned with the connection points 4001a, 4002a, 4003a of the counter electrodes <NUM>, <NUM>, <NUM>, and the pixel electrodes <NUM>, <NUM>, <NUM>. Each opening <NUM>-<NUM> thus provides an electronic via for electronic contact to an electrode.

<FIG> shows the silver pattern layer <NUM> that facilitates the connection between the circuitry (not shown in <FIG>) and the pixel cells. The silver pattern layer is also shown in <FIG>, where a portion of the layer <NUM> has been magnified. The silver pattern layer has a total of six connectors <NUM>-<NUM>, each with a silver conductor reaching a position on the silver pattern layer <NUM> corresponding to an opening <NUM>-<NUM> of the insulating layer <NUM>. An outline of the counter electrode layer <NUM> is also shown in <FIG> to illustrate the alignment of silver pattern layer <NUM> with the counter electrode layer <NUM>.

In this device, each respective first layer <NUM>, <NUM>, <NUM> of the three pixel cells thus has its own connector. The pixel cells can be connected to a circuitry (not shown in <FIG>) for detecting a change in capacitance in the pixel cells, and for applying a potential difference to the pixel cells for switching the state of the symbols, according to any of the configurations described in connection to <FIG>.

<FIG> shows a diagram of the measured capacitance in the three pixel cells of the device described in connection to <FIG> and <FIG>. The plots marked Seg <NUM>, Seg <NUM>, and Seg <NUM> correspond respectively to the left, middle, and right pixel cell as shown in <FIG>. There are six clear peaks in the diagram, which are marked with arrows <NUM>, <NUM>, <NUM>, <NUM>', <NUM>', <NUM>'. Each peak corresponds to a touch on one of the pixel cells, in the following order:.

This experiment clearly shows that the capacitance in a pixel cell increases in response to a touch. In general, the measured capacitance in pixel cells that are not subjected to a touch stays within a low baseline interval. It should be noted, however, that some disturbances are present. In particular, the measured capacitance in Seg <NUM> increases sharply at arrow <NUM>', i.e. when Seg <NUM> is touched. This may be due to the fact that the silver conductors <NUM> and <NUM>, connecting the counter electrode <NUM> and the pixel electrode <NUM> of the rightmost pixel cell overlap with the middle pixel cell, as illustrated in <FIG>.

Accordingly, it may be advantageous to arrange the different layers of an electrochromic display device to avoid or minimize any overlap between conductors associated with one pixel cell and other pixel cells.

Additionally, the capacitance data shown in <FIG> may be filtered to make it easier to correctly identify a touch on the respective pixel cells. As an example, an exponential moving average can be computed on the derivative of the measured capacitance of each pixel cell. Many different methods of filtering the data are possible.

An example of a more advanced type of user interaction made possible by the present disclosure is illustrated in <FIG> and <FIG>, which show an embodiment of an electrochromic display device <NUM> arranged to provide a game of Tic-Tac-Toe playable by touching the display to turn on the noughts and crosses.

The device <NUM> comprises a total of <NUM> pixel cells printed on the same substrate. <NUM> of the pixel cells, corresponding to the nine noughts and the nine crosses, are arranged in a 3x3 grid. In <FIG>, six layers <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM> of the display are shown, one by one, according to the following print order:.

The first layer <NUM> shown in <FIG> comprises a total of eleven physically separate electrochromic segments. Nine segments are arranged in a 3x3 grid of equal size square segments. For clarity of the illustration, of these nine segments, only the top-left segment <NUM> is labeled. A tenth <NUM> and eleventh <NUM> electrochromic segment is located on opposite sides of the 3x3 grid.

The symbol defining layer <NUM> (<FIG>) is arranged in direct contact with the first layer <NUM>. An opening in the shape of the cross <NUM>, surrounded by an opening in the form of a circle (nought) <NUM>, is aligned with each segment <NUM> of the 3x3 grid of the first layer <NUM>. There are thus nine crosses <NUM> and nine circles <NUM>, giving a total of <NUM> different symbols. In proximity to each circle <NUM> is a small opening <NUM> providing an electronic via, facilitating electronic contact with the corresponding segment <NUM> of the first layer <NUM>. An opening defining an upward pointing arrow symbol <NUM> and a small opening <NUM> are aligned with segment <NUM> of the first layer <NUM>. An opening defining a downward pointing arrow <NUM>, an additional rectangular opening <NUM>, and a small opening <NUM> are aligned with segment <NUM> of the first layer.

The third layer is the electrolyte layer <NUM> (<FIG>), which is separated into <NUM> electrolyte islands <NUM>, <NUM>, corresponding to the circle <NUM> and cross <NUM> shapes of the symbol defining layer <NUM>, and three additional electrolyte islands in the shape of an upward-pointing arrow <NUM>, a downward pointing arrow <NUM>, and a rectangle <NUM>, corresponding to the opening <NUM>, <NUM> and <NUM> of the symbol defining layer, respectively. Each electrolyte island fills its corresponding opening of the symbol defining layer <NUM> completely.

<FIG> shows the counter electrode layer <NUM>. It comprises <NUM> counter electrodes with shapes corresponding to the symbols, i.e. nine counter electrodes generally shaped as a cross <NUM> and nine counter electrodes generally shaped as a circle <NUM>. A pixel electrode <NUM> is located in proximity to each circle shaped counter electrode <NUM>, aligned with a corresponding opening <NUM> of the symbol defining layer <NUM>. The pixel electrode <NUM> facilitates electronic contact with the first layer <NUM>. Additionally, the counter electrode layer <NUM> comprises counter electrodes in the shape of an upward pointing arrow <NUM>, a downward pointing arrow <NUM>, and a rectangle <NUM>, as well as two pixel electrodes <NUM>, <NUM>.

The insulating layer <NUM> (<FIG>) has openings <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM> aligned with a connection point of each one of the counter electrodes <NUM>, <NUM>, <NUM>, <NUM>, <NUM> and pixel electrodes <NUM>, <NUM>, <NUM>. Each opening thus provides an electronic via for electronic contact to an electrode.

<FIG> shows the silver pattern layer <NUM> that facilitates the connection between the circuitry (not shown in <FIG>) and the pixel cells. There are a total of <NUM> connectors, each with a silver conductor reaching a position on the layer <NUM> corresponding to an opening of the insulating layer <NUM>. For example, connectors <NUM>, <NUM> and <NUM> provide a connection to the circle-shaped counter electrode <NUM>, the cross-shaped counter electrode <NUM>, and the pixel electrode <NUM> of the counter electrode layer.

In this configuration, the potential applied to each counter electrode and to each pixel electrode can thus be individually controlled. The nine circle symbols, the nine cross symbols, the arrows and the rectangle can consequently be individually turned on or off.

It should be noted that among the <NUM> pixel cells corresponding to the circles and crosses, each of the nine pairs of circles and crosses in the 3x3 grid is two pixel cells sharing a common first layer.

The pixel cells can be connected to a circuitry, for detecting a change in capacitance in the pixel cells, and for applying a potential difference to the pixel cells for switching the state of the symbols, according to any of the configurations described in connection to <FIG>.

<FIG> is an illustration of the device <NUM>, in top view, in use, i.e. during a game of Tic-Tac-Toe. For the purposes of the illustration, an outline of each pixel cell, i.e. of each circle <NUM>-<NUM> and of each cross <NUM>-<NUM>, is shown. Three cells are in the "on" state: the cross <NUM> in the lower-left corner of the grid, the cross <NUM> in the center of the grid, and the circle <NUM> in the upper-left corner of the grid. As seen in <FIG> The on-state and the off-state have two different visually detectable colouring states, the on-state may e.g. be more coloured and/or more opaque compared to the off-state. A first player has thus pressed on the display <NUM> to turn on one of the crosses <NUM> or <NUM>, followed by a second player having pressed the display to turn on the circle <NUM>, and the first player having pressed on the second cross <NUM> or <NUM>. In the state shown, it is the turn of the second player to press on one of the remaining squares of the game grid.

In use, the device <NUM> thus detects a touch (or an object in close proximity) of one of the nine squares of the game grid, and one of the symbols (circle <NUM>-<NUM> or cross <NUM>-<NUM>) of that square is turned on, depending on which player's turn it is.

With each pixel cell connected to a circuitry (not shown in <FIG>) according to a configuration as outlined in connection with <FIG>, the circuitry can determine a capacitance value signal for each of the <NUM> pixel cells. As noted above, each pair of circle and cross, e.g. <NUM> and <NUM>, is two pixel cells sharing a common first layer. It may be difficult to differentiate, in reading the respective capacitance value signals, between a touch of the circle and of the cross. However, a simple processing of the circuitry, keeping track of which player is playing the current turn, allows the correct symbol to be turned on.

Claim 1:
An electrochromic display device comprising a set of pixel cells, each pixel cell being arranged to display at least one symbol, which at least one symbol is repeatedly switchable between an on-state and an off-state, which on-state and off-state have two different visually detectable colouring states, wherein each pixel cell comprises:
a first layer (<NUM>) comprising electrochromic and electrochemically active organic polymer material being electrochemically switchable between said two different visually detectable colouring states,
a counter electrode (<NUM>) comprising an electrically conductive material
an electrolyte layer (<NUM>), which electrolyte is arranged spatially between, and in ionic contact with, said first layer and said counter electrode,
a symbol defining layer (<NUM>) which is electronically and ionically insulating arranged in direct contact with said first layer, and which symbol defining layer comprises one or more openings defining the shape of said symbol, wherein said electrolyte layer fills said openings of said symbol defining layer,
a pair of connectors (<NUM>, <NUM>), each connector in electronic contact with a respective one of said first layer and said counter electrode,
wherein said counter electrodes of said set of pixel cells are electrically separated from each other, and
the device further comprises:
a circuitry in electronic contact with each connector in said pair of connectors of each pixel cell of said set of pixel cells, which circuitry is configured to be connected to a power supply, and which circuitry is further configured to selectively provide a respective potential difference between said pair of connectors of each pixel cell in said set of pixel cells at least when connected to said power supply,
wherein said circuitry is further configured to
detect a change in capacitance in at least one pixel cell of said set of pixel cells, said change in capacitance being caused by an external object in close proximity to said at least one pixel cell, and
switch a subset of pixel cells of said set of pixel cells between one of said on-state and said off-state and the other of said on-state and said off-state, in response to said change in capacitance exceeding a predetermined threshold, by providing said respective potential difference between each one of said pair of connectors of said subset of pixel cells.