CS258857B1 - Method of wheat grain's potential yield determination from small sectors - Google Patents

Abstract

The purpose of the speech is to determine the selection method to and from new-born strains wheat even from very small parts in the early generations had found a potential hectare grain yield. The essence is that that ee at maturity is ecologically optimal the blades of the upper two sheets of productive stele falling in the stand per square meter of land, first on the component measures the area of the upper blades two sheets of average productive straw, harvested at maturity set of ears to determine average weight grains on the cob and further out of the environment the optimum blades of the upper two blades on productive stalks falling in per square meter of soil the area of the blades of the upper two leaves the average productive straw, calculate the number of ears of a given area of one square meter of land. and finally from the calculated number of ears to one square meter of land and the average weight the grain on the ear calculates the potential yield - grains of one square meter, β by subsequent conversion to yield per hectare grains.

Description

The present invention relates to a method for determining the potential yield of wheat grain from small pieces where, in early-generation wheat strains, due to lack of seed, normal varietal trials cannot be established, yet it is desirable to know their yield possibilities for selection.

So far, the selection of wheat strains for area grain yield has been made according to the partial yield characteristics of the plants, various selection indices and finally based on the grain yield measured from several square meters of crop after harvesting by small-scale machinery, grain purification and weighing.

The current shortcomings in determining the yield potential of early generations of wheat breeding mainly due to their inaccuracy removes the method of determining the potential yield of wheat grain from small parts according to the invention, which is based on the fact that Btéble per stand per square meter of soil, first measured on the panel by measuring the blade area of the upper two leaves per average productive straw, harvested a set of ears to determine the average grain weight per ear and then ecologically optimal area of the top two blades The number of ears per productive area is calculated from the area of the blades of the upper two leaves per average productive stem, calculated from the area of the blades of the upper two leaves per product. and, finally, the potential grain yield per square meter is calculated from the calculated number of ears per square meter of soil and from the determined average grain weight per, followed by conversion to a hectare of grain yield.

Said method of determining the potential yield of wheat grain from small pieces allows selection of strains for area grain yield in early generations, which will lead to a shortening of the breeding process and possibly to a reduction of the experimental areas.

- 2 Early identification of the yield potential of wheat strains will also facilitate the much desirable systematic breeding for yield stability of varieties of different grades.

An example of how to determine the potential yield of wheat grain from small pieces.

Two new breeds of winter wheat sown by a machine on 2 m ² pieces were compared, in the vicinity of Prague, where the ecological optimum of the area of upper two leaf blades on productive stalks per 1 m ^{2 of} soil is around 3 m ² . Healthy vegetation was used, otherwise preventive chemical protection would be necessary in case of impending leaf diseases.

On the twenty productive stalks of each new breed, selected according to the so-called main, large ears, the blade areas of the upper two leaves were measured by measuring the length and maximum width of the leaf in cm to one decimal place instead and multiplied by 0.7 . Alternatively, said leaf area can be detected directly by a portable area · * by meter. During the measurement, the ears were marked, harvested at the time of maturity, the grain was threshed and cleaned on the ear threshing machine, weighed in grams, and after dividing the weight of the grain by the number of ears, the average weight of the ear was determined. The ecologically suitable area of the upper two leaf blades per cm of productive wheat blades, in 2 per 1 m of land, in our case 30,000 cm, was divided by the average area of the upper two leaf blades per cm of new refinement to determine the average the number of stalks per 1 m of vegetation involved. The first no2 breeding showed 60.3 cm per stalk and 498 ears per 1 m, the second by analogy 52.4 cm and 573 ears. Since the grain weight per ear was 1.83 g of the second refinement, 1.76 g, then multiplying the number of ears to 1 m and the grain weight per ear revealed a potential hectare yield of 9.11 t for the first refinement, while the second 10 So, in the given year, the selection of the second refinement seems to be more advantageous in terms of potential grain yield.

Claims (1)

Method of determining the potential yield of wheat grain from small parts, characterized in that knowing the ecologically optimal area of blades of the upper two leaves on the productive stalks per stand per square meter of soil, the area of the upper two leaves blades per average productive harvest of ears to determine the average grain weight per ear, and from the ecologically optimal area of the upper two-leaf blades to productive stalks per hectare of one square meter of soil, and from the observed area of the upper two-leaf blades per average productive stalk, calculate the number of ears per square meter of soil, and finally, from the calculated number of ears per square meter of soil and from the determined average grain weight per ear, the potential grain yield and one square meter, followed by conversion to hectare grain yield ·