WO2012104187A1

WO2012104187A1 - Measurement device for determining a vegetation index value

Info

Publication number: WO2012104187A1
Application number: PCT/EP2012/051181
Authority: WO
Inventors: Tobias Haas
Original assignee: Georg Fritzmeier Gmbh & Co. Kg
Priority date: 2011-02-04
Filing date: 2012-01-26
Publication date: 2012-08-09
Also published as: DE102011003647A1

Abstract

The subject matter of the invention is a measurement device for determining a vegetation index value ("REIP") of plants, in which a plurality of light transmission elements are provided, each of which emits substantially monochromatic light with a predetermined wavelength. A light receiving element receives the light from the light transmission elements reflected by the plants and generates a signal indicating the respective intensity of the received light. A control device controls the light transmission elements in cyclically successive measurement sections, which are in each case assigned to one of the predetermined wavelengths, ascertains the intensity of the light reflected in each measurement section from the output signal of the light receiving element, and finally calculates the vegetation index value from the ascertained intensities of all measurement sections. The invention provides that the control device switches off that light transmission element in each measurement section of a predetermined wavelength which emits the light of that wavelength and switches on all other light transmission elements.

Description

description

Measuring device for determining a vegetation index value

The present invention relates to a measuring device for determining a vegetation index value (REIP) of plants according to the preamble of claim 1 and to a measuring method of this type according to the preamble of claim 10.

Measuring devices of this type are known for example from US 2006/0208171 A1 or US 2008/0291455 A1. These known measuring devices serve to determine a vegetation index value of plants; In particular, the so-called "REIP" vegetation index should be determined with this known measuring device ("Red Edge Inflection Point"). Plant measurements of this kind are used to obtain the measured quantities obtained for the determination of the most important parameters of the plant, namely in the case of the REIP vegetation index, above all for the determination of the instantaneous nitrogen content of the measured plants; From the determined nitrogen content it is then possible to set up a suitable fertilization plan for the relevant field; in practice, e.g. already using appropriate GPS-based fertilizer systems, which use the determined nitrogen values for an optimal, area-accurate fertilizer supply.

The known vegetation index measurements are based on the light absorption or reflection behavior of plants shown in FIG. 3. Accordingly, the plants have the general property of absorbing light of specific wavelengths (namely <700 nm) while absorbing the longer-wavelength light (ie> 800 nm) nm) reflect. As can be seen from FIG. 3, the blue, green and red portions of light are absorbed by the leaves of the plant, the cell structure and the water content of the plant causing absorption in the incipient infrared range to occur on a steep flank ("red edge ") turns into a reflection.

Investigations have shown that this Red Edge Inflection Point (REIP) transition zone can be used to determine the chlorophyll content as well as the nitrogen content of plants. Namely, there is the relationship shown in Figure 4 between the REIP value of the plant and their nitrogen content, and it was shown by Guyot and Baret (1988) that four measurements with different wavelengths are sufficient to determine the nitrogen content.

In the aforementioned US 2006/0208171 A1 it is therefore proposed, for example, to provide four light-emitting elements in the form of light-emitting diodes (LEDs) for the measurement of the REIP value and thus of the nitrogen content, each of which is essentially monochromatic light of a predetermined wavelength within the REIP range (ie in the range between 660 and 780 nm); a control device controls these four light-emitting diodes in cyclically successive measuring sections, which are each associated with one of the predetermined wavelengths, and determines the intensity of the light reflected in each measuring section from the output signal of the light-receiving element. From the determined intensities of the entire measuring cycle, ie all four measuring sections, the currently present vegetation index or REIP value is finally calculated.

It has been shown in practice that the accuracy of the measurement is strongly influenced by variations in the ambient light. In order to reduce these negative influences on the measurement result, it is proposed in the German patent application with the application number 102009036148.0-52 to provide a light-frequency converter as a light-receiving element, wherein a current control device is further provided, the current supplied to each light-emitting element controls and which is adjusted so that each light-emitting element generates the same output signal at a defined distance to a defined white area in the light frequency converter. Studies have shown that fluctuations in ambient light can be compensated to a certain extent by a halogen lamp. A complex compensation of the ambient light, as proposed for example in US Pat. No. 7,408,145 B2, can thus be dispensed with.

However, it has been shown that even such a compensation then leads to measurement errors when the measurement at dusk or at night, so with very little or no residual light is performed. To solve this problem, the German patent application, also not previously published, proposes 102009052159.3-52 to provide a controlled via a pulse width modulation circuit bulb that illuminates the plants to be detected at dusk or night. Although it has been shown that useful measured values can be obtained in the dark, the heating of the LEDs and sensors arranged in their immediate vicinity caused by the incandescent lamp inevitably leads to temperature-induced measurement errors. Such errors must then, if at all possible, be compensated in a complex manner.

The invention has the object of providing a measuring device for determining a vegetation index or REIP value of plants according to the preamble of claim 1 in such a way that the measurement accuracy can be increased with little effort even in low light conditions. Furthermore, with the invention, a corresponding measurement method should be specified.

This object is achieved with respect to the measuring device with the measures specified in the characterizing part of claim 1 or with respect to the method with the method steps specified in the characterizing part of claim 0.

The invention therefore proposes that the control device in each measuring section of a predetermined wavelength switches off the light-emitting element which emits the light of this wavelength, while it switches on all other light-transmitting elements. It has been found that with this type of activation of the light-emitting elements changes in the ambient light can be compensated in a much simpler manner. For example, it is sufficient in practice to provide the correction factor given in claim 5 in the calculation formula of the REIP value.

The invention thus achieves a high measurement accuracy even in dark light conditions, without the hardware complexity would be required, so that the circuit complexity is not increased according to the invention. Further advantageous developments of the invention are the subject of the dependent claims.

The invention will be explained in more detail below with reference to the description of an embodiment with reference to the drawing. Show it:

Fig. 1 is a block diagram of an embodiment of the invention;

Fig. 2 is a schematic representation of a typical application of the invention;

3 shows a schematic representation for explaining the absorption / reflection behavior of plants; and

4 shows the relationship between the REIP value and the nitrogen content of plants.

1, the measuring device schematically designated 1 consists of a central control device MC, which may be, for example, a commercially available microcontroller, an oscillator or oscillation circuit OSZ, which requires the time base required for the frequency measurement (of 40 MHz in the exemplary embodiment). a power control module LED-C for LEDs LED1 to LED4 and a light / frequency converter L / F, which may be, for example, the type TSL 230 R. Communication takes place via the interface IO1, which is designed as a serial interface and generates a Bluetooth signal.

The four light-emitting diodes LED1 to LED4 generate light of different wavelengths, namely the light-emitting diode LED1 light with 670 nm, the LED2 light with 700 nm, LED3 light with 740 nm and the LED4 light with 780 nm; each of these light-emitting diodes has a half-width of the emitted light between 20 and 30 nm. To exclude fluctuations in brightness caused by the supply voltage of these light-emitting diodes, the current supplied to them is regulated via transistors of the current control module LED-C. The current regulations of the individual light-emitting diodes are adjusted so that they produce the same output frequency at a defined distance from a defined white area in the light after the conversion in the light / frequency converter L / F. This white balance ensures that both the Series dispersion of the LEDs as well as the spectral sensitivity of the

Light / frequency converter is balanced.

The measuring device according to the invention operates as follows: The central control device MC, in order to carry out a measuring cycle, controls the light-emitting diodes LED1 to LED4 one after the other for a predetermined period or period via the current regulation module LED-C. The duration of this period is dimensioned such that the light / frequency converter L / F generates an output pulse. At each rising edge of the light / frequency converter L / F, the measurement is activated by counting the processor clocks via a gate. At every falling edge of the

Light / frequency converter L / F, the measurement is stopped via the gate. The number of processor clocks counted during such a measurement section is therefore a direct measure of the light intensity to be detected.

In total, each measurement cycle consists of four consecutively performed measurement sections, each of which is associated with one of the four predetermined wavelengths and is performed over a predetermined period of time.

In the first measuring section, the intensity of the reflected light is detected, which is assigned to the wavelength 670 nm. For this purpose, the light-emitting diode LED1 is turned off for the predetermined period of time while the light-emitting diodes LED2, LED3 and LED4 are turned on, so that the plants shown schematically in FIG. 1 are illuminated with light of the wavelengths 700 nm, 740 nm and 780 nm; the light reflected from the plants is then received by the light / frequency converter L / F and the central control device MC determines from the time duration (or the number of processor clocks) between the edges of the output signal of the

Light / frequency converter L / F the light intensity P1 associated with the wavelength 670 nm, which is a measure of the reflectance at this wavelength. This determined light intensity P1 is then stored.

In the second measuring section, the intensity of the reflected light is detected, which is assigned to the wavelength 700 nm. For this purpose, the light emitting diode LED2 is turned off for the predetermined period of time while the light emitting diodes LED1, LED3 and LED4 are turned on, so that the plants are illuminated with light of the wavelengths 670 nm, 740 nm and 780 nm; the light intensity P2 determined from this is a measure of the reflectance at the wavelength 700 nm and is also stored.

In the third measuring section, the intensity of the reflected light is detected, which is assigned to the wavelength 740 nm. For this purpose, the light emitting diode LED3 is turned off for the predetermined period of time while the light emitting diodes LED1, LED2 and LED4 are turned on, so that the plants are illuminated with light of the wavelengths 670 nm, 700 nm and 780 nm; the light intensity P3 determined from this is a measure of the reflectance at the wavelength 740 nm and is also stored.

Finally, in the fourth and last measuring section, the intensity of the reflected light associated with the wavelength 780 nm is detected by turning off the LED 4 for the predetermined period of time while turning on the LEDs LED 1, LED 2 and LED 3 so that the plants are exposed to light the wavelengths 670 nm, 700 nm and 740 nm are illuminated; the light intensity P4 determined from this is a measure of the reflectance at the wavelength 780 nm and is stored.

After completion of such a measuring cycle consisting of four measuring sections, all four measured values for the light intensities P1 to P4 are then stored in the central control device MC; these values are used in the following formula:

REIP = λ ₂ + (λ ₃ - λ ₂ ) ((Ρι + P ₄ ) / 2 - P ₂ ) / (P ₃ - P ₂ ) in which the values Pi to P ₄ , as explained, in each case the measured intensity of Reflection light of the relevant light emitting diode LED1 to LED4 and λ-ι, λ ₂ , λ ₃ and K4 respectively denote their specific wavelength (ie the values 670, 700, 740 and 780 nm). The calculated value REIP of this formula is a direct measure of the nitrogen content of the plant (s) irradiated by the light emitting diodes in the relevant measurement cycle.

To correct the ambient light dependence of the measured value, the formula above must be supplemented by a correction value as follows:

REIP = λ ₂ + (λ ₃ -λ ₂ ) ((Ρι + P ₄ ) / 2 -P ₂ ) / (P ₃ -P ₂ ) - (P ₄ / Pi -1) * 100

Investigations have shown that using the described four measuring sections and the above formula even at dusk or even in complete darkness acceptable readings can be achieved.

According to FIG. 1, a signal is sent via the interface 101, which signal indicates the calculated value for the vegetation index REIP. This signal is received by a computer PC containing a software-mapped fertilizer system; This fertilizer system is able to determine the amount of nitrogen required per hectare, in order to be able to control a fertilizer spreader, for example. In addition, the amount of nitrogen measured at the position in question can be determined by means of a GPS sensor in order to perform a corresponding map production or documentation.

The measuring cycle described above is continuously repeated after passing through all four measuring sections and after calculating the value REIP, so that an almost complete detection of the nitrogen content of all sampled plants is possible depending on the speed of movement of the measuring device.

According to Figure 2, the measuring device according to the invention may be attached, for example in duplicate to a tractor. The recorded or calculated data is transmitted via the Bluetooth connection of the interface IO1 to the tractor. So there is no cable connection in the cabin of the tractor necessary. A PC in the tractor can carry out the evaluation of the data calculated in the sensor according to the invention. For this purpose, the data is provided with GPS positions and, for example Displayed online. In the PC are stored plant knowledge and yield maps. A fertilizer spreader can therefore be suitably controlled by the PC.

Claims

claims

1. Measuring device for determining a vegetation index value (REIP) of plants, with

a plurality of light emitting elements (LED1 - LED4), each of which emits substantially monochromatic light of a predetermined wavelength,

a light-receiving element (L / F) which receives the light reflected by the plants of the light-emitting elements and generates a signal indicating the respective intensity of the received light, and with

a control device (MC), the

the light-emitting elements in cyclically successive measuring sections, which are each associated with one of the predetermined wavelengths, drives,

the intensity of the light reflected in each measuring section is detected from the output signal of the light-receiving element (L / F) and

calculated from the determined intensities of all measuring sections the vegetation index value (REIP),

characterized in that

the controller (MC) in each measurement section of a predetermined wavelength turns off the light emitting element (e.g., LED1) emitting the light of that wavelength and turns on all other light emitting elements (e.g., LED2 - LED4).

2. Measuring device according to claim 1, characterized in that as light transmitting elements four light-emitting diodes (LED1 - LED4) are provided, each having a wavelength of 670 nm (λ-ι), 700 nm (λ ₂ ), 740 nm (λ ₃ ) or 780 nm (λ ₄ ), wherein the control device (MC)

1) switches off the LED1 in the first measuring section provided for detecting the intensity of the wavelength 670 nm (λ-1) and turns on the LED2, the LED3 and the LED4,

2) in the second measuring section provided for the detection of the intensity of the wavelength 700 nm (λ ₂ ) switches off the LED 2 and switches on the LED 1, the LED 3 and the LED 4, 3) in the third measuring section provided for detecting the intensity of the wavelength 740 nm (λ ₃ ) switches off the LED 3 and switches on the LED 1, the LED 2 and the LED 4, and

4) turns off in the provided for the detection of the intensity of the wavelength 780 nm (λ) fourth measuring section, the LED4 and the LED1, the LED2 and the LED3 turns on.

3. Measuring device according to claim 2, characterized in that the half-width of the light emitted by the light-emitting diodes (LED1 - LED4) light is between 20 and 30 nm.

4. Measuring device according to claim 3, characterized in that the control device (MC) as the vegetation index value, the REIP value ("Red Edge Inflection Point") calculated according to the following formula:

REIP = λ ₂ + (λ ₃ - λ ₂ ) ((P + P ₄ ) / 2 - P ₂ ) / (P ₃ - P ₂ ) in which the values Pi to P _{4 are} each the measured intensity of the reflection light in the designate the measuring section associated with the respective wavelength.

5. Measuring device according to claim 4, characterized in that the control device (MC) corrects the formula for correcting the ambient light dependence of the detected intensities as follows:

REIP = λ ₂ + (λ ₃ - λ ₂ ) ((P ₁ + P ₄ ) / 2 - P ₂ ) / (P ₃ - P ₂ ) - (P ₄ / Pi -1) * 100

6. Measuring device according to one of claims 1 to 5, characterized in that the light-receiving element is a light frequency converter (L / F).

7. Measuring device according to claim 6, characterized by a current control device (LED-C), which controls the current supplied to each light-emitting element and which is adjusted so that each light-emitting element in a defined distance to a defined white area in the light frequency converter (L / R) produces the same output signal.

8. Measuring device according to one of claims 1 to 7, characterized in that the control device (MC) uses the REIP value as a measure of the nitrogen content (N) of the measured plant.

9. Measuring device according to claim 8, characterized in that the control device (MC) preferably feeds the respectively determined nitrogen content to a mobile, preferably GPS-supported fertilizer system (DS) via a Bluetooth interface (101).

10. Method for determining a vegetation index value (REIP) of plants, in which

the plants to be measured are irradiated with a plurality of light emitting elements (LED1 - LED4), each of which emits substantially monochromatic light of a predetermined wavelength, and

receive the light of the light emitting elements reflected by the plants and generate an intensity signal indicating the respective intensity of the received light,

wherein the light-emitting elements are driven in cyclically successive measuring sections, which are each assigned to one of the predetermined wavelengths, the intensity of the light reflected in each measuring section is determined from the intensity signal, and the vegetation index value (REIP) is calculated from the determined intensities of all measuring sections .

characterized in that

in each measuring section of a predetermined wavelength, the light emitting element (e.g., LED1) emitting the light of that wavelength is turned off and all other light emitting elements (e.g., LED2 - LED4) are turned on.

11. The method according to claim 10, characterized in that as light-emitting elements four light-emitting diodes (LED1 - LED4) are provided, each having light of wavelength 670 nm (λ-ι), 700 nm (λ ₂ ), 740 nm (λ ₃ ) or 780 nm (λ ₄ ), wherein 1) in which is provided for the detection of the intensity of the wavelength 670 nm (λ-ι) provided the first measuring section LED1 and the LED2, the LED3 and the LED4 are turned on,

2) in the second measuring section provided for the detection of the intensity of the wavelength 700 nm (λ ₂ ) the LED 2 is switched off and the LED 1, the LED 3 and the LED 4 are switched on,

3) in the third measuring section provided for detecting the intensity of the wavelength 740 nm (λ ₃ ) the LED 3 is switched off and the LED 1, the LED 2 and the LED 4 are switched on, and

4) in the provided for the detection of the intensity of the wavelength 780 nm (λ) fourth measuring section, the LED4 is turned off and the LED1, the LED2 and the LED3 are turned on.

12. The method according to claim 1 1, characterized in that the vegetation index value of the REIP value ("Red Edge Inflection Point") is calculated according to the following formula:

REIP = λ ₂ + (λ ₃ - λ ₂ ) ((P ₁ + P ₄ ) / 2 - P ₂ ) / (P ₃ - P ₂ ) in which the values Pi to P are respectively the measured intensity of the reflection light in the designate the measuring section associated with the respective wavelength.

13. The method according to claim 12, characterized in that for correcting the ambient light dependence of the detected intensities, the formula is corrected as follows:

REIP = λ ₂ + (λ ₃ - λ ₂ ) ((Ρτ + Ρ ₄ ) / 2 - Ρ ₂ ) / (Ρ ₃ - Ρ ₂ ) - (Ρ ₄ / Ρ ₁ -1) * 100