BE891575R - STEP AND MOTION COUNTER, DIGITAL ROUTE CALCULATOR, MOTION VIEWER USING JEWELRY AND LIGHT EMITTING DIODE ELECTRONIC FIGURES - Google Patents

Description

       

  INTRODUCTION

  
It is interesting to know the number of steps taken during a walk or a run or to have an estimate in the chosen measurement unit (meters, centimeters, feet, etc.) of the length of the distance traveled on foot or on horseback or to know precisely the distance traveled by a vehicle (bicycle, motorbike, etc.) It is also useful to have a measurement of the forward speed whether on foot , on horseback or with a vehicle.

  
It is also advantageous to be able to automatically count repetitive movements performed in gymnastics or sport (for example the number of breaststrokes in swimming,

  
the number of pedal pedal strokes, etc.).

  
The invention which is discussed below makes it possible to carry out these operations and also applies to the programming of a route, giving the successive distances and directions to be taken to make a predetermined route.

  
(on foot, on horseback, by bicycle or by any other vehicle).

  
The invention also applies to the creation of a jewelry store

  
 <EMI ID = 1.1>

  
colored light-emitting diodes whose moments of illumination can be programmed according to the movements of the body.

  
To these lamps, one can also add sound sources emitting sounds programmed according to the rhythmic movements of the body.

  
Finally, the process in its extension can be used for various board games.

DESCRIPTION OF THE PROCESS

  
Motion sensor

  
To intercept a movement, you can use a

  
photocell, a contact or effect system

  
capacitive (digital key) or a mechanical system based

  
on gravity or inertia.

  
We have chosen the following system for its simplicity:

  
when approaching with a permanent magnet a contact

  
with magnetic paddle, this one which was initially

  
open closes when the magnet is nearby: it

  
opens when the magnet is removed.

  
This contact can be reversed: initially, one of the contacts

  
is normally open and the second, normally closed.

  
By the approach of the magnet, these contacts are reversed

  
and they rep: return to their initial position if the magnet is moved away.

  
Magnetic sensor layout

  
The arrangement of the magnetic sensors depends on

  
the application.

  
In principle, the elements (contacts and magnets) are fixed

  
separately opposite each other on the two parts

  
mobiles whose relative movement we want to control. By

  
example, to count the steps, we place one of the elements

  
on one leg and the other on the other leg, opposite;

  
at the crossing of the legs, the magnet approaching the

  
contact closes this one which activates an electronic system

  
count.

  
To intercept the movement of the arms, the parties to

  
consider are, on the one hand, the arm itself and, on the other hand, the torso. The elements, cuntact and magnet, are also arranged so that, in the movement,

  
at some point they come to stand close to each other.

  
For cycling, just attach the magnet on the wheel between

  
two spokes, near the hub, for example, and the other

  
part hung on the fork, at a sufficient distance

  
 <EMI ID = 2.1>

  
 <EMI ID = 3.1>

  
Regarding certain movements like those,

  
more complex, performed in gymnastics, it may be better to use a capacitive sensor placed, for example, at the fingertip.

  
Touching another part of the vine gives a counting impulse (the feet, for example)

  
Other types of sensors

  
 <EMI ID = 4.1>

  
The magnetic chip is housed in a molded part

  
(made of plastic) fitted with clamping tabs
(like those used in electrical wiring).

  
For the placement of this device on the wheel, a place or two pairs of spokes crossing each other near the hub are chosen. The piece with its magnet is stretched between these spokes by pulling on the tabs. One can also provide a hooking system by pinching the part containing the magnet at the intersection of two pairs of spokes.

  
Preferably, the tab system is used to attach the magnet to the pedal board.

  
The magnetic contact is housed in a plastic tube. It is easily attached to the fork or the frame at the magnets.

  
 <EMI ID = 5.1>

  
An axis, a rod, one end of which pivots around the axis

  
and the other end holds a magnet or a metallic or non-metallic piece, acts as a pendulum.

  
The magnet in its oscillating movement approaches a

  
or several magnetic contacts.

  
Magnet stroke adjustment stops are also provided so as to be able to adjust the proximity of the magnet to the magnetic contact (s).

  
One can also provide magnetic or ferromagnetic stops having a pendulum retaining effect at the desired locations.

  
The magnetic contacts can be replaced by microswitches or contact pads activated by the pendulum.

  
 <EMI ID = 6.1>

  
A metal part or one or more balls move in a tube. At the ends of this tube are fixed micro-switches which are actuated by the pressure of the moving parts when they come into abutment under the effect of gravity.

  
An external magnet can exert an adjustable effort to retain the moving part.

  
You can replace the micro-switches with pads

  
contacts fixed on an insulating elastic support. The balls or the metal part can come to vermerate the circuit by coming to abut on these pellets.

  
One can also close an electrical circuit through the tube itself.

  
The presence of a magnet placed upstream of these pellets

  
contact exerts a pushing force both on the wall of the tube and on the contact pads.

  
Magnetic contact

  
To improve the problems of rebounding when the contacts are closed, provision can be made for them to be secured to a permanent or electromagnetic magnet possibly fixed on an elastic support. The mobile contact is made in the same way.

  
The movable contacts and the fixed contacts stick to each other by magnetic pressure.

  
Walk sensors

  
In Figure 1 is shown an assembly for accurately counting the impulses of a walker

  
to count them and get the distance traveled and

  
forward speed.

  
The sensor consists of a support fixed to the belt, containing a micro-switch or a magnetic contact and on which a flexible rod (nylon, plastic) is articulated,

  
movement is controlled by the movement of the thigh.

  
The displacement of the rod activates a micro-switch or a magnetic contact whose magnet is integral with the rod.

  
The angle from which the rocking contact is adjustable.

  
The length of the tive is itself adjustable.

  
In the figure, there is also shown the calculator placed in a removable housing, fixed in the belt.

  
In Figure 2, a similar system is shown suitable for

  
the leg of a horse.

  
Electrical connections

  
The process uses a type of electrical connection specially designed to easily attach to clothing or underwear. The terminal blocks are made with press studs, one of the elements of which (male or female) can be directly sewn onto the garment.

  
There are also fabric small pieces on which press buttons on one side or on both sides come out; these elements are electronically connected with each other, depending on the circuit to be produced.

  
These coins can themselves hang on clothes or underwear by means of snaps or other systems (pins, velcro, etc ...)

  
The interconnection wires are either integrated into the weft of the garment, or woven with it, or housed in an independent sheath provided with pressures.

  
One can also provide in the clothing and underwear suitable conduits in which the electrical wires are introduced. Any other model of electrical connection by plugs is also possible.

  
 <EMI ID = 7.1>

  
Counting electronics

  
It is easy to build an electronic circuit capable

  
count the pulses intercepted by the sensors described above. The originality of the invention consists in using the pocket calculators which need only be made suitable for counting pulses outside the machine.

  
Let us introduce into the machine a connection socket which we designate as input socket.

  
This input socket is internally connected to the terminals of the closing circuit of the key, the repeated pressing of which makes the successive additions of the same number initially introduced with an addition sign in the calculator; (on some machines, this is

  
of the key =). Via this socket,

  
we can connect the external magnetic contact of which

  
closing is equivalent to pressing the corresponding key. The modified machine can therefore be used

  
to count the external impulses.

  
It is easy to understand that by entering the number representing the average length of a step into the calculator, the distance traveled on foot will be obtained on the calculator display dial. To find out the distance traveled by bicycle, simply enter in

  
the calculator the number equal to the perimeter of the wheel.

  
The wire connection between the sensor and the calculator

  
can possibly be ensured by radio wave. Speed indicators

  
Pocket calculator can be adapted to display

  
forward speed. She must have ,. for this purpose, a time base as is the case of stopwatch calculators. In fact, the calculator can, at any time, divide the distance traveled by the time 'necessary to complete this route, using an average time for this calculation, fixed or adjustable.

  
Counting wheel

  
To find out, in the unit of your choice, the length between two determined points or any route, you will use a graduated wheel at the periphery on which is fixed, laterally, a magnet. At each revolution of the wheel, the magnet will activate a magnetic contact, the circuit of which is connected to the calculator. This calculator can be slipped into a case integral with the handle of the wheel.

  
A mark is visible in front of the start of the count.

  
At the end of the course, we will add the number of the peripheral graduation which is opposite the reference.

  
This wheel is particularly suitable for architects, surveyors, gendarmes and, in this case, the caster is provided with an extension handle.

  
Pro gr ammée signaling

  
Having obtained a counting device and a route calculator, it is possible to program a route or a sports training, etc.

  
To do this, let's introduce an output socket and a few additional keys on the keyboard into the pocket calculator.

  
We will not go into the details of the internal electronic circuits to insist on the new functions requested from the calculator.

  
Program recording

  
There is a "counting" button on the calculator;

  
by pressing this key, you can save,

  
via the normal keyboard, the number of pulses transmitted to the calculator necessary for it

  
delivers a signal (logic) to its output socket.

  
Depending on the capacity of the machine, several successive numbers can be registered by means of a similar operation.

  
To each of these numbers, it is possible, by means of a signaling key, to match an output signal applicable to an electronic device.

  
signaling.

  
Thus, in Figure 3, a pocket calculator is represented with its counting and signaling keys

  
 <EMI ID = 8.1>

  
of the motion sensor.

  
The signaling device designed outside the calculator can optionally be incorporated into it.

  
 <EMI ID = 9.1>

  
1 to 12 and, next to each of these lamps, there is a reading window showing the indications written on a program sheet.

  
With this machine, you can, for example, program a route with 12 distinct stages. The data relating to each of these stages are entered on the program sheet, next to the windows.

  
This program is entered into the calculator using the "counting and signaling" keys. As and when

  
 <EMI ID = 10.1>

  
 <EMI ID = 11.1>

  
quer successive step changes. A sound top can also draw attention to the different step changes.

  
Other models of pocket calculators can be specially studied for specific applications:
- compass calculator (figure 4).

  
The compass can be attached to or outside the machine. On the compass dial are distributed indicator lights or liquid crystal dots indicating the direction expressed in degrees.

  
The calculator is equipped with a "counting" key and a "direction" key and an input socket and an output socket, if the compass is outside of it.

  
We program the route as follows:

  
press the "direction" key and enter on the keyboard the number representing the direction to follow in degrees. Then press the "count" button to enter the number of meters to travel in this direction. It is possible to continue programming the route in direction and distance in the same way, depending on the memory capacity of the calculator. This calculator being connected to the pitch sensor or the number of wheel turns of a vehicle, will be able, depending on the progress of the walker or the

  
 <EMI ID = 12.1>

  
A sound top can also be provided to attract attention when changing course.

  
Compass calculator with automatic route correction

  
In addition to the possibilities described above on

  
the pocket calculator associated with a compass,

  
it is possible to obtain the display of the distances separating the walker or the cyclist, etc ... from the initial programmed direction.

  
This distance will be affected by the positive or negative sign depending on whether the individual is in the space located

  
east or west of the programmed direction.

  
To achieve this performance, it is sufficient to plan on

  
the compass the possibility of measuring the angle between the programmed direction identified by the ignition of the segment

  
and the position of the magnetic needle (series of photocells arranged on the angular scale

  
of the compass, the magnetic needle obstructing a light or infrared source located opposite these cells

  
With this angle, the calculator will calculate the cosine and

  
will make the necessary correction automatically, of the real progress in the initially chosen axis, likewise, it will be able to give at any time the distance separating the walker from this same direction.

  
- Waterproof calculator for use in water
(Swimming)
- Watch calculator with input socket to obtain the counting result on the wrist.
- Calculator with two or more counting inputs with display and programming selected by keys or multiple dials for simultaneous display of counting results.

  
Interest of the counter and totalizer calculator

  
Spart

  
Schedule of sports training (running, swimming).

  
 <EMI ID = 13.1>

  
Programming of exercises.

  
Military

  
Plan a route or a training exercise.

  
 <EMI ID = 14.1>

  
Establish according to the professions the number of steps taken during a day:
- waiters, nurses, housewives, city dwellers, police, children, adults, old people, etc.

  
Scouting and various games.

  
The counter can be applied to wild or domestic animals to study their behavior and assess the distances traveled by them.

  
Electronic jewelry store with light-emitting diodes

  
Thanks to the motion sensor device and the technology of the electrical connections described above,

  
can create a new type of electronic jewelry. Light emitting diodes of various colors and shapes can be introduced into existing jewelry or be used as such for the creation of jewelry or new figures.

  
Illumination of diodes of the same color or arranged in a certain way can follow a lighting order

  
which is linked to the movements of the body (walking, dancing, etc.) One can also, with the addition of a simple electronic circuit, choose a repetitive ignition cycle accentuating a measure or a dance rhythm.

  
Use of light-emitting diodes for clothing

  
jewelry and electronic figures

  
To avoid assembly by welding, it suffices to drill a fine hole at the ends of the diode connection tabs (Figure 5). Power supply wires

  
are threaded through these holes. The construction of necklaces or bracelets is simple and accessible to children.

  
 <EMI ID = 15.1>

  
decorative beads are threaded onto the folded legs of the diodes, at the same time as a nylon wire or an insulating wire, taking care that there is overlapping of the legs of contrary signs under these beads.

  
For serial connection of these diodes, it suffices to introduce the supply wires into the holes of the end diodes.

  
 <EMI ID = 16.1>

  
power supply at the ends and one in the center of the collar, the diodes having a common starting point at this location.

  
Prefabricated module

  
Another method of assembling light emitting diodes for the construction of necklaces or various jewelry is to have

  
at its disposal prefabricated modules (Figure 6).

  
The diode legs are folded and provided with decorative beads. At the ends of these legs, additional pressure elements have been welded, the male element on

  
the positive branch of the diode and the female element on

  
the negative branch.

  
Other diode assembly systems can be provided using flexible connectors (Figure 7).

  
In the assembly of the diodes by beads, as described above, rubber beads or beads having a rubberized hole can be used so as to ensure pressure on the conductive tabs of the diodes.

  
Multi-take core

  
These nuclei of various shapes (cylindrical, spherical, cubic, etc.) can be fitted with luminescent diodes introduced into the female plugs of the nucleus.

  
Molded jewelry can also be provided with incorporated diodes or with housings for easy introduction of the diodes. (Rings, glasses, bracelets, etc ...)

  
Regarding the motion sensors
(for counting or for electronic jewelry)

  
we also designed a sensor that takes gravity and inertia into account.

  
This sensor consists of a single contact or reversing switch sensitive to the magnetic field and fixed on the external wall of an enclosure in which a permanent magnet is housed.

  
1. can move around under the effect of gravity or

  
 <EMI ID = 17.1>

  
In its movement, the magnet activates the contact.

  
To take account of the inertial forces generated by rapid movements, it suffices to place adjustable stops at the ends of the enclosure, and behind these stops, other adjustable magnetized or ferro-magnetic pads,

  
 <EMI ID = 18.1>

  
mobile may be greater than the force of gravity.

  
Only a quick movement can free the magnet from the stop: by sending it to the other end (counting steps, jumps, rider movements on his horse). To facilitate the movement of the movable element, it can be placed in an enclosure filled with a lubricating liquid.

  
Electrical connections by magnetic contacts

  
These contacts are suitable for their use on clothes and underwear. They consist on the one hand, of magnetic pads in which are provided a centering lug and copper contacts constituting the two poles to be connected and, on the other hand, magnetic plugs to ensure a good coupling of the two parts.

  
Interest of the process

  
This animated electronic jewelry can be used in clothing fashion with the creation of clothes garnished with light-emitting diodes, the lighting of which is associated with various movements of the body (walking, dancing, etc.). Manufacture of clothes and underwear with

  
electrical connections and housing or means

  
for fixing magnetic sensors.

  
Creation of new jewelry with light-emitting diodes integrated or not in traditional jewelry.

  
Educational assembly games for making light figures.

  
Embellish a music hall, cabaret show etc ...

  
and various board games.


    

Claims (46)

1) Method of counting steps characterized by a magnetic sensor associated with a pocket calculator. One of the elements of the magnetic sensor (for example the magnet) is placed on one leg (inside and up) and the other element (contact) being placed on the other leg at the same level. 2) This sensor is associated with an electronic control of the pocket calculator type modified by adding an input socket whose connections are connected in parallel on. the closing circuit activated by the appropriate keyboard keys. 3) Distance calculator. The adapted pocket calculator according to 2) allows you to match each pulse transmitted to entry by the external contact, the operation of repeatedly adding the number initially entered on the calculator. This number can be the average distance one step. 4) Distance calculator for cycle and vehicle. By placing the permanent element on a cycle wheel or a vehicle, so that every turn wheel, the magnet comes to pass in front of the fixed magnetic contact, we will obtain a cycle of pulses which could be introduced into the calculator described in 2). By entering on the calculator the number expressing the perimeter of the wheel in the chosen unit, we will get the distance display directly actually traveled by the vehicle in the same type of unit. 5) Pocket calculator associated with a motion sensor allowing the display of the distance traveled and forward speed. 6) Graduated wheel associated with a pocket calculator for measuring a length. 7) Counter characterized by an adjustable sensor fixed on a belt and provided with an adjustable rod actuated by the movement of the leg. The calculator associated with this sensor (magnetic contact micro-switches activated by the movement of the rod) can be placed in a case attached to the belt (Figure 1). 8) Magnetic sensor or micro-switches adaptable to a leg (horse ...) fixed below the knee with a movable rod actuated, by bending the leg (Figure 2). 9) Pitch and distance traveled counter as described in 2) and 3), is applicable to animals by providing an appropriate case to fix the magnetic sensor properly. 10) Addition to a pocket calculator of one or several input sockets attacking either two circuits calculator counting, or a single circuit alternately counting the input values selected by keys. 11) Addition to a pocket calculator of one or several output sockets capable of delivering logic signals to an external electronic circuit signaling. 12) Addition to a pocket news calculator functions controlled by keys (counting, signaling, direction) for programming precise signaling. 13) Pocket calculator according to 6), 7) and 8), associated with a electronic program signaling device using indicator lights or segments of liquid crystal and program sheets (Figure 3). This device can be integrated into the calculator or be external to it. The calculator input signal can come from a magnetic sensor or another type of progress sensor (odometer). 14) Use of a remote control at the input of the calculator. Closure of the external contact can be transmitted to the machine by radio link. 15) Pocket calculator associated with a compass and integrated to it or outside (Figure 4). A calculator key, a direction key and, optionally, a deviation key are provided on the calculator (direction). The compass dial has segments of liquid crystals or light-emitting diodes whose ignition is programmed by the calculator. <EMI ID = 19.1> come from a magnetic contact or other device. 16) Pocket calculator associated with a compass for the programming of a route and automatic control of the real distance carried out along the chosen direction axis and making it possible to give distances of affected deviations  <EMI ID = 20.1> with respect to the programmed steering axis. The compass measures the angle between the programmed direction and the direction taken by the traveler (photocells next to the magnetic needle), this angle is introduced into the calculator which establishes the necessary corrections by the value of the sine and the cosine. 17) Waterproof pocket calculator for its use in the water or outdoors (placement on the handlebars  <EMI ID = 21.1> 18) Watch type calculator with input socket for wrist count display. Same type of calculator as in 13), but housed in a pendant. 19) Calculator with two or more dials for the simultaneous display of several counts. 20) Electrical connection made by means of pressure one of the elements of which can be sewn to the garment or undergarment. 21) Small piece of fabric or leather fitted with press contact on one side or on both sides and interconnected with each other depending on the type of electrical diagram to be produced. These pieces can easily be attached to clothes or underwear by snaps or other simple systems (velcro, etc ...) 22) Electric conductors integrated in the frame of the garment or underwear, the threads being covered with a fabric of the same kind as the weft. 23) Use of multi-strand cables housed in sheaths fabric that can easily be attached to clothing and underwear with press studs or passing tabs. 24) Specially designed clothing or underwear with conduits in which we can pass the multi-strand cables. These cables can be fitted with connection plugs at their ends or with one of the  <EMI ID = 22.1> designate the + and the female part the -). 25) Trousers specially adapted for step counting comprising for example on the top of the right leg a housing for a magnet (small pocket inside or outside the pants) or fixing pressures and on the left leg at the same level a similar housing for the magnetic contacts. A possible conduit for the electric wires joining the pocket or the belt can be provided as well as the connection sockets by pressure or plugs and a pocket for the calculator.  <EMI ID = 23.1> of a new type of electronic jewelry. These diodes can be attached to traditional jewelry or used to make new types of jewelry in association with pearls, etc. 27) Drilling the ends of the diode connections (fig. 5) luminescent to be able to thread the electrical connection wires while retaining the possibility of sliding decorative beads on these same connections which can serve as a system for assembling the diodes together. 28) Making necklaces, bracelets or other figures  <EMI ID = 24.1> interchangeable. On each diode are strung decorative beads beforehand and at the ends are  <EMI ID = 25.1> branch + of the diode and, on the other hand, the female element on the other branch (Figure 6). 29) Flexible connector for light-emitting diodes for seamless making of necklaces, bracelets etc ... (fig 7) 30) You can also add to an illumination cycle LEDs of sound tops of different tones. Method including the production of fashion clothes dotted with decorative light-emitting diodes and with incorporated electrical circuits and pocket for electronic equipment and battery. The lighting of these lamps can be subject to various body movements and follow a chosen automatic cycle. 30) Method for lighting the light-emitting diodes automatically controlled by body movement (walking, dancing, movement of the arms etc ...) This process uses the magnetic sensors already described in 1) and placed at different places on the body. A simple electronic circuit makes it possible to obtain a cycle of illumination of the diodes according to the location they occupy or their coloring. It is also possible to obtain a lighting cycle selected by switch and which adapts to a specific measure or dance rhythm. 32) The process also calls for a new type of specially designed clothing and underwear to house magnets, magnetic contacts, connections and electrical circuits, as well as the electronic control device with its battery. 33) The process also calls for the realization of model cores for the construction of various electronic figures. These cores are provided with female plugs into which the legs of the light-emitting diodes are introduced. These plugs are connected inside the core in an accessible or non-accessible way. 34) It is also possible to provide connection plugs on flexible strips to cut, arranged regularly checkerboard, these being interconnected (series or parallel). 35) The process makes it possible to build play boxes educational materials including: an assortment of light emitting diodes, an assortment of beads, an assortment of cores, and interconnection cables as well as, in a more elaborate version, some magnets and . magnetic contacts and accessories such as batteries and electronic devices, and the calculator count. 36) Remote control of lighting LEDs included in decorative figures (jewelry etc ...) via photoelectric cells (sensitive to light or infrared) which are fixed on the person using these figures (also by ultrasound). 37) Conductive threads sewn by machine on a garment or underwear. 38) The counting and electronic jewelry process  <EMI ID = 26.1> based on the effects of gravity and inertia. It is a device with a magnetic contact placed on the wall of an enclosure in which a mobile element can circulate. The enclosure may be filled with water or a lubricating liquid. To take account of the effect of inertia of the movements, there are also provided at the ends of the enclosure, adjustable stops and magnetic pads with which one can adjust the retaining force of the movable magnet at the ends of the pregnant. 39) Pendulum sensor characterized by the displacement of a magnet in an oscillating movement with, arranged along this path, one or more magnetic contacts. Other magnetic or ferro-magnetic elements whose position can be adjusted along the path of the pendulum can exert a retaining effect of the latter in the desired locations. Magnetic contacts can be replaced by micro-switches or actuated contact pads by the pendulum in its movement. 40) Gravitational sensor characterized by a tube in which move one or more balls or a cylindrical metal part. At the ends of this tube are fixed micro-switches which are actuated by the pressure of the moving parts when they come into abutment under the effect of gravity. An external magnet can exert an adjustable force retainer on the moving part. The micro-switches can be replaced by contact pads fixed on an elastic insulating support. The balls or the metal part can come close the circuit by coming up against these pellets .. One can also close an electrical circuit through the tube itself. The presence of a magnet placed in amor.t of these contact pads exerts a thrust force both on the wall of the tube and on the contact pads. 41) Magnetic contact To improve the problems of rebounding when the contacts are closed, provision can be made for them to be secured to a permanent or electromagnetic magnet, optionally fixed on an elastic support. The mobile contact is made in the same way. Movable contacts and fixed contacts stick together to the other by magnetic pressure. 42) Magnetic sensor for bicycles, bicycle motors (spoked wheels). The magnet is housed in a molded part with clamping tabs. This piece is stretched between two pairs of intersecting spokes. The tabs can be replaced by a pinch hooking system. 43) Regarding electrical circuit connections on clothes or underwear, we can adopt a new type of contact with magnetic pads or magnetic cards. 44) In electronic jewelry, the use of self-  <EMI ID = 27.1> different legs of the light-emitting diodes. These beads can be rubber or elastic foam or beads of other hard, but hollow material, where an elastic material can be introduced. 45) In electronic jewelry, provision is also made resin or transparent and colored plastic jewelry molded with the possibility of housing light-emitting diodes or lamps. These light-emitting diodes can also be an integral part of molded jewelry. 46) We can also provide, in addition to 19), that the photocell, a contact system with magnetic paddle, or with capacitive effect (digital key) can be integrated into the calculator.