DE19724087A1 - Transmitting and receiving device for high-frequency radiation and method for high-frequency transmission - Google Patents

Description

The invention relates to a transmitting and receiving device for high frequency radiation and a method for high-frequency over wear with such a device.

High-frequency connections, for example after the DECT or GSM standard, form an important link at Informa tion transfer. Both mobile and sta conventional transmitters / receivers.

A typical field of application of the present invention is in the field of mobile telecommunications.

A commercially available handheld mobile phone that according to works according to the GSM standard, radiates a high overall frequency power from about 2 W to connect to a to produce a fixed base station. The required broadcast performance, the reception field strength and ultimately also the portable data rate (bandwidth) are here by the geome trie (distance between transmitter and receiver) and by elemen tare thermodynamic laws (signal to noise ratio).

High-frequency transmitters, such as those used in a mobile phone, radiate their energy essentially in a 4πr ² geometry. For the high-frequency connection, however, only the solid angle component is used, which is directed in the direction of the receiver.

In particular, mobile transmitters and receivers often have to with an independent energy source like batteries or Batteries that only have a limited amount of energy operate. The resulting relatively short Operating time is a big problem with these devices represents.

The object of the present invention is a Transmitting and receiving device for high frequency radiation as well as a  Procedure for high-frequency transmission with this device give that with the same energy supply an increased operating has duration. It also aims to improve the high frequency connection are made possible.

The task is accomplished with the features of the applicable claims 1 and 17 solved. Advantageous refinements are the subject of subclaims.

According to the invention, a transmitting and receiving device for high frequency radiation provided with an antenna is equipped with a directional, inertia has changeable radiation characteristics. The device is continue to be equipped with an auto matical, inertia-free alignment of the radiation char Statistics in the direction of a second transceiver (Remote station) in real time.

This device is advantageously by a Bün of the transmission lobe (directional radiation characteristic) the required transmission power in the direction of the second device with unchanged field strength at the receiver compared to conventional devices significantly reduced (by at least one Magnitude). This leads especially to battery or accumulator operated devices to significant energy savings and thus increasing the operating time of the device. The here for the automatic tracking of the transmission lobe in Real-time additional energy required is compared to the ins overall achievable energy savings are negligibly small.

This results in the case of permanently installed transmitting and receiving devices in addition to the energy saving, the advantage that the court radiation characteristics when installing the device first start-up in a new location automatically aligns so that no separate adjustment he is required. The same applies to a change  Position of the second device requires no readjustment Lich, since the first device in its radiation characteristics Automatically adapts in real time to the new conditions, d. H. on aligns the new position.

Another advantage of the invention is the reduction of high frequency energy unnecessarily dissipated into the environment ("Electric smog").

The directional radiation characteristic continues to bring Increase of the effectively usable transmission channels with it, since this can avoid overlaps.

In an advantageous embodiment, the transmission / Receiver device means that the half-width of the beam lung characteristic in a main beam direction (direction with maximum power density) in real time so that optimal transmission of data at high frequency radiation is guaranteed. The full width at half maximum is included the angle between the directions with a half as large Power density as in the main beam direction (3 dB width) On the one hand, optimal transmission of data can mean that the transmission process through the spatial bundling with drastically reduced transmission energy can occur; on the other hand can be maintained or only slightly reduced Transmit energy higher transmission rates can be realized because by bundling significantly higher field strengths at the reception place occur.

In a further, particularly advantageous embodiment of the present invention includes the transceiver one or more acceleration sensors. The output signal of these sensors is fed into a device that the current spatial position of the device or a fictitious device axis, for example in the normal towards the level of the antenna array, with respect to  calculated a reference axis. When the room changes Liche location of the device is the orientation of the radiation characteristic automatically based on this calculation current position.

Movements of the device can be performed using micromechanical sensors accelerated and possibly integrated acceleration sensor be detected with high precision. The extremely high rake performance of microelectronic circuits makes it possible here at, the device's own movement using the integrated Sensors in real time in a current location description of the To convert the device.

Hand-held phones in particular are usually moved during operation. With these movements, angular velocities of up to 5 s ^-1 can occur, so that the automatic tracking of the directional radiation characteristics in hand-held telephones must take place at speeds of this magnitude.

A significant relief when tracking the beam Lung characteristics can be achieved by including the determined values of the mechanical device movement at the Alignment of the radiation characteristics can be achieved. To do this, one or more acceleration sensors determine the Own movement of the device. This movement will take a moment tane alignment of the device axis with respect to a reference axis converted. A computing processor in the device then has that Task, taking into account the radiation characteristics track the current alignment of the device axis.

Motion detection with the help of acceleration sensors can be the one obtained by determining the direction of reception Alignment of the radiation characteristics in the direction of the second device, for example a base station, under support. In particular, in periods with missing or very little self-movement of the device on a constant Redefinition of the direction and / or realignment of the beam  characteristics and the associated computing effort to be dispensed with.

For example, at a specific start time, e.g. B. when turning on the device, the direction of the second Device determined and the radiation characteristics of the An tenne can be aligned accordingly. From this point the automatic tracking can be based on the Detec tion of the device's own movement by means of acceleration tion sensors are made. If necessary, usually moderate intervals or if the Transmission quality again the direction of the second device be determined (new start time).

The determination of the device's own movement with acceleration sensors and their use for the alignment of the Radiation characteristics also have the advantage that these Sensors can detect very fast movements precisely, so that misalignment due to a quick move be avoided.

According to another embodiment of the present invention the determination of the direction of incidence becomes that of the second Device (remote station) received high-frequency radiation the signals of a phase array antenna.

The definition of the radiation characteristic of an antenna for both transmitting and receiving operation can be carried out by means of several phase-shifted dipoles or radiation elements with a similar effect. This principle is known as the phase array antenna. Phase arrays are mainly used in the military sector as rapidly swiveling radar lobes for scanning a certain solid angle component. The achievable bundling properties of phase array antennas are essentially a function of the quotient antenna dimension / wavelength. For example, for the vertical radiation of a 3 × 3 array with overall dimensions of 4 × 4 cm ^2, a maximum opening angle of the radiation of 32 ° (drop of 3dB) can be estimated. This corresponds to a solid angle ratio of 1: 0.0625 (factor 16).

To determine the direction of incidence of the object tion received high-frequency radiation, the device Unit for determining the phase relationship of the one individual dipoles of the array detect signals. An inte The processor calculates the direction of incidence of the Remote station received high-frequency radiation from the Pha relationship. This direction becomes a reference axis of the Device sets in relation, and the radiation characteristics optimal field strength in the direction of the opposite station tet.

Due to the technical developments in recent years, especially the possibilities for inexpensive integration from electronic components to the upper Ghz Range, such as through advances in SiGe transistors it is also possible to use all electronic elements of the device Can be inexpensively integrated on a single substrate.

The invention is described below with reference to exemplary embodiments play in connection with the drawings.

Here show:

Figure 1 shows an example of the schematic structure of a transceiver according to the present invention.

FIG. 2a shows a device according to FIG 1, which is designed as a hand-held telephone. and

FIG. 2b shows a detail of Fig. 2a schematically shows the structure of the phased array antenna.

The invention is explained below using a mobile handphone 11 .

The basic structure of the device according to the invention is shown in Fig. 1. The antenna device consists of a phase array antenna 1 , which are connected to a transmit / receive split element 5 via amplifiers 2 , transmission / reception switches 3 and units for phase shifting / weighting 4 of the individual elements 12 of the antenna. On the one hand, the Splitele element 5 establishes a connection to the other signal-processing components of the hand-held telephone (conventional cell-phone components). On the other hand, a signal is derived to element 6 for determining the angle of the incident high-frequency radiation, and from this to an element 7 for determining the optimal radiation direction, from which units 4 for phase shifting the individual elements are finally controlled via split element 5 . Furthermore, the device can contain acceleration sensors 8 , from the data of which an angular correction of the radiation direction can take place in an element 9 . A device 10 for determining the absolute position of the device by means of the GPS method can also be provided.

The bundling of high-frequency radiation always uses one correlated wavefront ahead. This can be done through reflection (e.g. using parabolic mirrors), diffraction (e.g. using lenses or electrically controllable dielectric phase shifters plates) and by direct phase-related control of neighboring single radiators. The latter represents the fastest and easiest way of realizing an antenna device with directed radiation characteristics. The associated high-frequency and radiation technology Properties, especially the resulting bundling factor gates, the solid angle and a further increase in Directional pattern through a reflector behind the antenna nenarray, are known to the expert and are not here described in more detail.  

Prerequisite for a meaningful application of the invention a handheld phone is that the high frequency wel used lenlength approximately corresponds to the antenna dimension. This Be The condition is with the current GSM standard (frequency range of 900 Mhz or 1.8 Ghz corresponding to a wavelength range of 33 cm or 17 cm) not to be fulfilled, because the dimensions a phase array antenna for a hand-held telephone may be large. However, it is foreseeable that in the near future coming for reasons of the required bandwidth or Channel number of increasingly shorter wavelengths for operation be released by hand phones.

A hand-held telephone according to the invention is shown in Fig. 2a. The hand-held telephone 11 , which works for example in the frequency range of 12 GHz, contains a phase array antenna 1 integrated into the housing. The phase array antenna consists, for example, of 3 × 3 dipoles 12 . To shorten the effective wave length, this dipole array is additionally embedded in a material with a comparatively high dielectric constant and low loss angle. In particular, polymers such as polycarbonate (ε ≈ 2.2 at 10 GHz) are suitable as materials, which can also be processed relatively easily as casting compounds. With a dielectric constant of 2, such an array has total dimensions of approximately 4 × 4 cm ² in the frequency range mentioned. This corresponds to the usable area of a handheld system or a chip card.

Fig. 2b schematically shows the integrated phase array antenna in the housing 1 with the dipole. By suitable control of the dipoles 12 , the beam characteristic can be controlled so that the main beam direction 14 deviates from the surface normal 15 of the array plane at any angle. The phase array antenna is provided on the back with a shield 13 . This shielding can be done, for example, by integrating the antenna array into a material with electrical shielding properties on one side, such as, B. is known from DE 44 33 330 can be realized.

Process for controlling the dipole array in phase, to switch between transmitting and receiving mode, or the Selection of the wavelengths according to the heterodyne or PLL ver driving are already known from high-frequency technology. The extensive integration of all broadcasting Driver and receive amplifier on a single substrate. This is made possible by new developments at Integra tion technology, such as the development of SiGe Transistors for the high transmission frequencies as well SOI (Silicon On Insulator) techniques.

When initiating the transmission to a usually fixed base station, the receiver of the mobile determines the direction of the incoming high-frequency radiation. This information can be obtained from the phase relationship of the signals detected by the individual dipoles 12 of the antenna array. The computing processor integrated in the mobile device determines this direction, places it in relation to a geometric reference axis of the mobile device and optimizes the transmission and reception characteristics of the antenna for optimal field strength in the direction of the base station. After the beam characteristics have been aligned, the transmission energy is reduced to the extent necessary to achieve the field strength required at the receiving location. This is done in the same way as the feedback method already used in the GSM standard.

The method described is suitable for both mobile devices as well as for base stations. A currently advancing Ent winding refers to the replacement of wired Transfer of data (e.g. telephone, etc.) to comparative short distances through high-frequency connections (DECT standard). These are permanently installed High frequency transmission lines. By the establishment  of a device according to the invention with self-adjusting frets development and alignment of the antenna lobe can Sta on the one hand, simplified installation and on the other with considerably reduced transmission power.

It is also conceivable to transmit and receive the invention gear in card form. Devices in card form, similar in size to the chip currently in use cards, especially for short-range transmission in the 1st .100m range it will become increasingly important in the future The area of such a chip card is very good for opening suitable phase array antenna. The reduction and Geometric alignment of the transmission energy helps the middle one Reduce exposure to electromagnetic radiation and additionally a higher number of straightening sections with the same Frequency to operate. With these essentially stationary operated transmitting and receiving devices in card form are in particular the self-aligning orientation of the Radiation characteristics and the self-regulating reduction the transmission energy is an advantage.

In a preferred exemplary embodiment, the hand-held telephone has one or more 3-axis acceleration sensors 8 which continuously record the device's own movement (cf. FIG. 1). This movement is converted into a current alignment of the device axis with respect to a reference axis. For example, the spatial axis 15 perpendicular to the antenna array plane can be used as the device axis, which is identical to the axis of the radiation maximum (main beam direction) when all dipoles are in phase. The computing processor in the device then tracks the radiation characteristics taking into account the current alignment of the device axis.

This motion detection can support the orientation of the radiation characteristic obtained by determining the receiving direction in the direction of the second device. Especially in the case of reflections and interference, such as occur when a radio connection is operated close to the ground, the determination of the transmitter position from the received signal or its phase position is a comparatively complex, iterative and time-consuming method. By including the data from the acceleration sensors 8 , an unnecessarily frequent implementation of this method of determining the direction can be avoided.

Due to the mechanical position / acceleration determination furthermore problems caused by a 180 ° rotation of the Device in relation to the effective antenna axis (Forward / back characteristic of the antenna array) recognized and ge may be corrected or displayed. In particular, in periods with missing or very ge ringer own movement of the device on a constant re-determination direction and / or realignment of the radiation pattern characteristics and the associated computing effort be tested.

Accelerometers for use in an invention modern device can with the methods of microsystem technology can be produced very inexpensively. They are also in the offing future as small, fully integrated components with ge low power consumption available.

The method is not considered to be a fixed base station second device limited, but can also between two mo bile devices are used. Another beneficial one Application can be in the alignment of the antenna lobe to earth satellites exist. The use of devices according to the invention ten can in particular with the so-called direct telecommunication cation via satellites serving as the opposite station in the near-earth Orbit bring significant benefits.

In a further embodiment, provision can be made to support the alignment of the radiation characteristic and / or the selection of an optimal connection path by determining the absolute position of the mobile device. This position can be determined, for example, using the GPS system (cf. FIG. 1). For this purpose, the mobile device determines its position and uses a saved list to select the fixed remote stations in question. The list of Ge counter stations can either be permanently stored in the device or advantageously be updated when the device is switched on for the remote stations in question by transmitting information from the remote stations to the handset.

This method of determining the position can also be used for all purposes determination of the alignment of the radiation characteristic serve in cases where the spatial direction of the devices axis of the transceiver is immutable (for example play with a permanently installed device).

Claims (24)

1. transmitting / receiving device for high frequency radiation with an antenna device (1) having a directional, inertia modifiable radiation pattern, and means (2 - 7) for automatic, inertia-free alignment of the radiation pattern in real time in the direction of a second transmitting / receiving device. 2. transmitting / receiving apparatus according to claim 1, characterized in that the means (2 - 7) comprises means for adjusting the half-value width of the radiation pattern in a main beam direction in real-time so that an optimum transmission is ensured development of data with the Hochfrequenzstrah . 3. Transceiver according to claim 1 or 2, characterized in that the device has one or more acceleration sensors ( 8 ), the output signal of which is fed into a device ( 9 ) which the current spatial position of the device with respect to a reference axis calculated. 4. transmitting / receiving apparatus according to claim 3, characterized in that the means (2 - 7) comprises means (7) that performs at a change in the spatial position of the device the orientation of the radiation coulter file ristik on the basis of the calculated current position. 5. transmitting / receiving apparatus according to any one of claims 1 to 4, characterized in that the means (2 - 7) comprises means for determining the direction of incidence of the received from the second device high-frequency radiation. 6. Transceiver according to claim 5, characterized in that the means a unit for Determination of the phase relationship that of the individual Dipoles of the array detected signals and a built-in processor that includes the direction of incidence the radio frequency radiation received by the second device calculated from the phase relationship, this direction too relates to a reference axis of the device, and the Radiation characteristics to optimal field strength in rich device of the second device. 7. Transceiver according to one of claims 1 to 6, characterized in that the device means ( 10 ) for absolute position determination of the device, in particular by means of the GPS method, and for selecting a second device from a stored or transmitted list with second device positions, the mean position and the position of the selected device being used as information or additional information for the alignment of the radiation characteristics. 8. Transceiver according to one of claims 1 to 7, characterized in that the antenna device ( 1 ) is a phase array antenna. 9. Transceiver according to one of claims 1 to 8, characterized in that the antenna device ( 1 ) is integrated in the device housing. 10. Transmitting / receiving device according to one of claims 1 to 9, characterized in that the antenna device ( 1 ) is embedded in a material with a high electrical dielectric constant. 11. Transmitting / receiving device according to one of claims 1 to 10, characterized in that the antenna device ( 1 ) is applied or integrated on or in a base material which has an electrically shielding property on one side. 12. Transceiver according to one of claims 1 to 11, characterized in that all electronic components of the device are integrated on a single substrate. 13. Transceiver according to one of claims 1 to 12, characterized in that the device is mobile. 14. Transceiver according to claim 13, characterized in that the device is a hand-held telephone is. 15. Transceiver according to claim 13, characterized in that the device is card-shaped from measurements, in particular chip card format. 16. Transceiver according to one of claims 1 to 12, characterized in that the device is a fixed Base station is. 17. Transceiver according to one of claims 1 to 16, characterized in that the second device is a mobile Handheld phone, a fixed base station or a Is satellite. 18. A method for high-frequency transmission with a transceiver according to the preceding claims, in which the direction of a second transceiver is determined and the radiation characteristics of the antenna device ( 1 ) in real time automatically and without inertia in the direction of the second transmitter. / Receiving device it is aligned. 19. The method according to claim 18, characterized in that the half-width of the radiation characteristic in one Main beam direction is set in real time so that optimal transmission of data at high frequency radiation is guaranteed. 20. The method according to claim 18 or 19, characterized in that the current spatial position of the device with respect to a reference axis is calculated from the output signal of one or more acceleration sensors ( 8 ). 21. The method according to claim 20, characterized in that after the initial investigation development of the direction of the second transceiver Alignment of the radiation characteristics on the bottom location of the calculated current location. 22. The method according to any one of claims 18 to 21, characterized in that the direction of the second Transceiver from the direction of incidence of the second device received high-frequency radiation becomes. 23. The method according to claim 22, characterized in that the direction of incidence of the high-frequency radiation received by the second device is determined from the phase relationship of the signals detected by the individual dipoles ( 12 ) of the array, related to a reference axis of the device, and the radiation characteristic is aligned to optimal field strength in the direction of the second device. 24. The method according to any one of claims 18 to 23, characterized in that the absolute position of the Device, in particular by means of the GPS method, with  telt, a second device from a saved or transferred list with second device positions selects, and the direction of the second device based on the determined position and the position of the selected Device is determined.