AT506707B1 - DEVICE FOR CONTACTLESS DISTANCE MEASUREMENT BETWEEN TWO MEASUREMENT SITES - Google Patents

Description

Austrian Patent Office AT506 707B1 2009-11-15

Description: [0001] The invention relates to a device for contactless distance measurement between at least two measuring points with the measuring points associated measuring devices interconnected by a radio link, each having an oscillator stage for generating a frequency-modulated in the sense of a ramped frequency response measurement signal, a transmitting and receiving unit for the measuring signals, as well as a mixing unit connected to an evaluation stage for the measuring signals generated in the respective measuring device and received by the other measuring device, and with at least one computer stage connected to the evaluation stages of the measuring devices for calculating the measured data evaluated in the evaluation stages and for output the calculated distances.

In order to ensure an advantageous radar measurement of the distance between two measuring devices, it is known (DE 101 57 931 A1) to emit a frequency-modulated measuring signal with a ramp-like frequency response from one of the measuring devices and this received by the other measuring device measuring signal with a in the receiving Measuring device in a consistent manner with the measurement signal generated comparison signal to mix, so that between the frequency response of the generated in the receiving measuring device comparison signal and the frequency response of the received measurement signal a constant, on the one hand by the duration of the measurement signal between the two measuring devices and on the other hand by the mutual time shift results between the measuring signal and the comparison signal dependent frequency difference, from which the distance between the measuring devices can be determined in a known manner, if the time shift between the measuring signal and V equalization signal is known. However, the accuracy of the time and frequency-related synchronization of the oscillators for the measuring and the comparison signal necessary for a corresponding sensitivity of the distance measurement is considerable, which precludes a comparatively simple construction.

[0003] In order to eliminate the need for precise timing of the oscillators in the two measuring devices, it has already been proposed (Stefan Scheiblhofer et al., "Performance Analysis of Cooperative Radar Distance Measurement Systems FMCW" in IEEE MTT-S International Microwave Symp. 121-124, Atlanta, USA Jun. 2008), on the one hand to transmit the measurement signals generated coincidentally in both measuring devices to the respective other measuring device and, on the other hand, to mix with the respectively received measuring signal in order to determine the respective frequency difference between the ramps in both measuring devices via an evaluation stage to determine the frequency response of the transmitted and received measurement signals, because by a calculation of these two depending on the duration of the measurement signals and the time shift between the measurement signals of the two measuring devices frequency differences, the time shift can be eliminated. The disadvantage is above all that comparatively complex precautions must be taken in order to transmit the evaluated measurement data with the aid of the receiving and transmitting units via the measuring radio link between the measuring devices.

The invention is therefore based on the object, a device of the type described for contactless distance measurement between at least two measuring points in such a way that with a low cost, a high-resolution distance measurement is possible.

The invention solves this problem by the fact that the evaluation stage of at least one of the measuring devices is connected to one of the transmitting and receiving unit for the measuring signals separate transmission unit for wireless transmission of the evaluated measurement data to the computer stage.

By providing a separate transmission unit for the transmission of the evaluated measurement data, conventional protocols for data transmission can be used, whereby the design effort on both the transmitter side and especially on the receiver side comparatively small and on proven components back Austrian Patent Office AT506 707B1 2009-11-15 can be used. For data transmission itself, the measuring radio link between the measuring devices can be used, with the advantage of using a radio link required for the transmission of the measuring signals. If the transmitting unit connected to the evaluation stage is connected to the computer stage via a data transmission path separate from the measuring radio link between the measuring devices, then the measuring radio link between the measuring devices can be used exclusively for the transmission of the measuring signals, which is an advantageous prerequisite for the accurate detection of high Speed-changing distance ratios is because the measurement radio link is not additionally burdened by the transmission of the evaluated measurement data and thus the transmission rate of the measurement signals is limited. Particularly advantageous conditions arise in this context, if already existing networks, preferably wireless networks for mobile communication, used and the case-proven facilities are used, so that the potential application can be considerably expanded.

The computer stage for billing the evaluated with respect to the frequency differences measured data can be assigned in a conventional manner at least one measuring device and summarized with the evaluation of this measuring device to a common computer unit. However, there is also the possibility of providing a separate output device from the measuring devices with the computer stage for offsetting the evaluated measured data, because only the evaluated measured values from the evaluation stages of the measuring devices are to be transmitted to this computer stage, which also has a temporal Delay can occur. It is only important to ensure that the assignment of the measured data evaluated in the two measuring devices is not lost.

In the drawing, the subject invention is shown, for example. 1 shows a device according to the invention for non-contact distance measurement between two measuring points in a simplified block diagram, FIG. 2 shows a representation corresponding to FIG. 1 of a variant embodiment of the device according to the invention, [0011] FIG Frequency curve of the transmitted and received measuring signals of the measuring device of one of the two measuring points and Fig. 4 shows the temporal frequency curve of the transmitted and received measuring signals of the measuring device of the other measuring point.

1, the two each associated with a measuring point measuring devices 1.2 are the same and each have a controllable via a control unit 3 oscillator stage 4 for a measurement signal in the microwave range, whose frequency is modulated in the sense of a ramped frequency response. Although not mandatory, a linear increase or decrease in the frequency response is sought. The frequency-modulated measuring signal is fed to a transmitting and receiving unit 5. The transmitting and receiving units 5 of the two measuring units 1 and 2 are connected to each other by a measuring radio link 6. The measuring signal received by the respective other measuring device 1, 2 is fed to a mixing unit 7, in which the received measuring signal is mixed with the measuring signal to be transmitted in order to apply a mixed signal to an evaluating stage 8 connected to the mixing unit 7. After a corresponding evaluation of the mixed signal, the evaluated measurement data are forwarded via the control unit 3 after a corresponding processing to a transmitting unit 9, which is connected to a computer stage 10 via a separate from the measurement radio link 6 data transmission link 11, in particular a radio network 12 for mobile communication. The evaluated measurement data of the two measuring devices 1 and 2 are therefore provided to the computer stage 10 for offsetting and for output of the calculated distances.

In Figs. 3 and 4, the temporal frequency characteristics of the transmitted and received measurement signals of the two measuring devices 1 and 2 are illustrated. From Fig. 3, 2/7 Austrian Patent Office AT506 707B1 2009-11-15 which relates to the measuring device 1, one recognizes the ramp-shaped course of the frequency response fi of the measured signal sent at the time t0, in Fig. 4 is the frequency curve f2 of in the measuring device 2 transmitted measuring signal visible. This measuring signal is sent delayed with respect to the measuring signal of the measuring device 1 by a time Toff and reaches the measuring device 1 after a running time τ. The measuring signal received by the measuring device 2 in the measuring device 1 is thus opposite the measuring signal of the measuring device 1 by a period of time T0ff + τ offset, which of course also in the displacement of the Frequenzveriaufs f2 'of the received measurement signal shows. Since the frequency difference Δf, = L-f2 'is constant because of the parallel ramp course of the frequency responses fi and f2', the sign-dependent frequency difference results from the known slope k of the ramped frequency characteristic according to FIG. 3 to Δή = k (Toff + τ).

In an analogous manner calculated according to FIG. 4, the frequency difference AfM from the frequency characteristics f2 and fi 'of the transmitted and the received measurement signals of the measuring device 2 to

Afe = k (i-Toff).

If the frequency differences Af, and AfM are offset by an addition to each other, the running time is τ = (1 / 2k) (fi + fn), and thus the distance d between the two measuring devices 1 and 2 at an assumed propagation velocity c0 of the electromagnetic waves to d = (c0 / 2k) (fi + fn).

Since from the mixed signals, the constant frequency difference can be determined for example by a Fourier transform, the distance d of the two measuring devices 1,2 can be determined independently of the time delay Toffder sent signals fi and f2. It is only to ensure a corresponding overlap of the frequency ramps of the transmitted and the received measurement signals and thus for a corresponding order of magnitude of the frequency difference, which may require a rough Vorsynchronisierung based on the time difference between the transmitted and received measurement signal.

In the evaluation stages 8 of the two measuring devices 1 and 2, the mixed signals in the sense of determining the frequency differences Afj and ΔίΗ are evaluated to account for the evaluated measurement signals in the computer stage 10 for determining the distance d. Because of the separate data transmission path 11 for the transmission of the evaluated measurement data, the measurement radio link 6 is not subjected to any additional load due to a data transmission and remains free for the transmission of the measurement signals. Due to the separate data transmission link 11 and the computer stage 10 can be assigned to a separate from the measuring devices 1,2 output device 13.

The embodiment of FIG. 2 differs from that of FIG. 1 only in that the computer stage 10 is assigned to one of the two measuring devices 1, 2, so that the distance determination in this measuring device, in the embodiment, the measuring device 2, performed is, as described in connection with Figs. 3 and 4. But it can also be assigned to both measuring devices 1, 2 computer stages 10, as indicated by dashed lines in Fig. 2 for the measuring device 1. In this case, ensure a mutual exchange of data between the two measuring devices 1 and 2. In the assignment of the computer stage 10 to the measuring devices 1,2, the right 3/7

Claims (6)

Austrian Patent Office AT506 707B1 2009-11-15 nerstufe 10 are summarized with the evaluation stage 8 to a common computer unit 14, which preferably also includes the control unit 3. In Fig. 2, dash-dotted lines indicated that the measurement radio link 6 can also be used for data transmission, if z. B. the transmitting unit 9 of the measuring device 1, the antenna of the radio link 6 with the appropriately formatted, evaluated measurement data acted upon. 1. Apparatus for non-contact distance measurement between at least two measuring points associated with the measuring points, interconnected by a radio link measuring devices, each having an oscillator stage for generating a frequency-modulated in the sense of a ramped waveform frequency measurement signal, a transmitting and receiving unit for the measurement signals, as well as an an evaluation stage connected mixing unit for the generated in the respective measuring device and received by the other measuring device measuring signals, and with at least one connected to the evaluation stages of the measuring devices computer stage for calculating the evaluated in the evaluation levels measurement data and output of the calculated distances, characterized in that the evaluation stage (8) of at least one of the measuring devices (1, 2) is connected to a transmission unit (9), which is separate from the transmitting and receiving unit (5) for the measuring signals, for wireless transmission Operation of the evaluated measurement data to the computer stage (10) is connected. 2. Device according to claim 1, characterized in that the evaluation unit (8) connected to the transmitting unit (9) via the radio link (6) between the measuring devices (1,2) to the computer stage (10) is connected. 3. A device according to claim 1, characterized in that the evaluation unit (8) connected to the transmitting unit (9) via one of the measuring radio link (6) between the measuring devices (1,2) separate data transmission path (11) with the computer stage (10). connected is. 4. The device according to claim 3, characterized in that the data transmission path (11) between the computer stage (10) and at least one of the evaluation stages (8) of the measuring devices (1,2) is part of a radio network (12) for mobile communication. 5. Device according to one of claims 1 to 4, characterized in that the computer stage (10) and the evaluation stage (8) in at least one measuring device (2) are combined to form a common computer unit (14). 6. Device according to one of claims 1 to 4, characterized in that the computer stage (10) is assigned to one of the measuring devices (1,2) separate output device (13). 3 sheets of drawings 4/7