CN111596313A

CN111596313A - Regional four-pest quantity detection system and application method

Info

Publication number: CN111596313A
Application number: CN201910130045.3A
Authority: CN
Inventors: 车文武; 梅兰
Original assignee: Shenzhen Yulong Environmental Protection Industry Co ltd
Current assignee: Shenzhen Yulong Environmental Protection Industry Co ltd
Priority date: 2019-02-21
Filing date: 2019-02-21
Publication date: 2020-08-28
Anticipated expiration: 2039-02-21
Also published as: CN111596313B

Abstract

The invention discloses a regional four-pest quantity detection system and an application method, belonging to the field of four-pest control systems, comprising a central control system and a plurality of mobile phones APP arranged in mobile phones of workers, wherein the mobile phones APP comprise a sampling data uploading module and a GPS positioning and sending module, the central control system comprises a regional data input module, a storage module, a regional division module, a regional three-dimensional map establishing module, a drug dosage calculating module, a regional data visualization module and a display module, the drug dosage of four-pest medicines is automatically calculated according to the four-pest density detected by the workers, the drug dosage of the four-pest medicines is filled into a three-dimensional map model of a pre-divided region, the three-dimensional map model is displayed to the workers for reference by the workers, the invention has the advantages of automatically calculating the drug dosage of the four-pest medicines and clearly and three-dimensionally displaying the drug dosage of the four-pest medicines in each region to the workers, the effect of facilitating the staff to accurately put in the medicine is achieved.

Description

Regional four-pest quantity detection system and application method

Technical Field

The invention relates to the technical field of four-pest control systems, in particular to a regional four-pest quantity detection system and an application method thereof.

Background

"four pests" were well-known, and 2.12.1958, am an instruction on the hygiene in removing four pests issued by the ministry of public health. It is proposed that the task of killing flies, mosquitoes, mice and sparrows be completed within 10 years or less. Gradually, the sparrow is "flat and inverted" and replaced by the bug. Later, the bed bugs are replaced by cockroaches due to changes in social life. Thus, the four pests are ultimately identified as flies, mosquitoes, mice, cockroaches. The four pest control is used as a PCO industry which is highly targeted and subdivided, and can meet the more and more vigorous environmental requirements, so that the four pest control is developed very rapidly in most regions of China, and various brand enterprises for four pest control gradually enter the lives of people. In the process of four-pest control, the number of four pests in the area needs to be monitored, and specific measures are taken for the number of four pests. The number of four pests is usually controlled by administering drugs in areas where four pests are likely to occur.

The above prior art solutions have the following drawbacks: usually, a company is responsible for environmental engineering in a large area, and because the area of the area is large and the situation is complex, the amount of the medicine to be put in is difficult to select for different areas, which is easy to cause waste or pollution.

Disclosure of Invention

The invention aims to provide a regional four-pest quantity detection system which can automatically calculate the dosage of four-pest medicines and clearly and stereoscopically display the dosage of the four-pest medicines in each region to workers, so that the workers can conveniently and accurately put the medicines.

The technical purpose of the invention is realized by the following technical scheme:

a regional four-pest quantity detection system comprises a central control system and a plurality of mobile phone APPs installed in a mobile phone of a worker, wherein each mobile phone APP comprises a sampling data uploading module and a GPS positioning and sending module;

the sampling data uploading module is used for the staff to input the detected four pest density information and send the density value of the four pest;

the GPS positioning and sending module automatically acquires the current position information of the staff and sends the position information;

the central control system comprises a region data input module, a storage module, a region dividing module, a region three-dimensional graph establishing module, a drug dosage calculating module, a region data visualization module and a display module;

the regional data input module receives the density values of the four pests sent by the sampling data uploading module and the position information sent by the GPS positioning sending module, and integrates the received density values and the position information of the four pests into data information to be output;

the regional three-dimensional map building module is used for building and outputting a three-dimensional map model by a worker;

the region division module receives the three-dimensional map model output by the region three-dimensional map building module, workers perform region division on the three-dimensional map model through the region division module, and the region division module outputs the divided three-dimensional map model;

the storage module receives the data information output by the area data input module and the three-dimensional map model output by the area dividing module, and stores the received data information and the three-dimensional map model;

the drug delivery amount calculation module calls the data information stored by the storage module, calculates the drug delivery amount of the four pesticides in each region according to the data information, and outputs the drug delivery amount of the four pesticides and the position information of the corresponding region;

the region data visualization module receives the dosage of the four pesticides and the position information of the corresponding region output by the dosage calculation module, calls the three-dimensional map model stored by the storage module, fills the dosage of the four pesticides into the corresponding region of the three-dimensional map model according to the position information of the corresponding region, and outputs the processed three-dimensional map model;

and the display module receives and displays the three-dimensional map model output by the regional data visualization module.

By adopting the scheme, the staff detects the four pest density of each region, after the detection result is input into the mobile phone APP, the central control system automatically generates the three-dimensional map model of the drug delivery amount of the four pest drugs and displays the three-dimensional map model to the staff, and the staff delivers the drugs to the regions according to the three-dimensional map model displayed by the central control system, so that the staff can conveniently and accurately deliver the drugs.

The invention is further configured to: the sampling data uploading module comprises a mouse density acquisition unit, a cockroach density acquisition unit, a fly density acquisition unit and a mosquito density acquisition unit; the worker inputs the estimated density of the mouse into a mouse density acquisition unit; the worker inputs the estimated density of the cockroaches into a cockroach density acquisition unit; the worker inputs the fly density into the fly density acquisition unit; the worker inputs the mosquito density into the mosquito density acquisition unit.

By adopting the scheme, the sampling data uploading module can input the density of mice, the density of cockroaches, the density of flies and the density of mosquitoes by a worker.

The invention is further configured to: detecting the density of the mice in the current area by a worker by adopting a visual mouse trace method or a mouse sticking plate method, and inputting the density of the mice into a mouse density acquisition unit;

the worker detects the density of the cockroaches in the current area by a cockroach sticking paper method and inputs the density of the cockroaches into a cockroach density acquisition unit;

the worker detects the fly density of the current area by a visual method or a fly sticking method and inputs the fly density into a fly density acquisition unit;

the worker detects the mosquito density of the current area through a spoon catching method and inputs the mosquito density into the mosquito density acquisition unit.

By adopting the scheme, the method for detecting the density of the four pests by the conventional method is scientific and reasonable, and the input data is accurate.

The invention is further configured to: the GPS positioning module comprises a GPS positioning unit and a response sending unit;

the GPS positioning unit acquires current position information in real time;

when the sampling data uploading module sends data to the area data input module, the response sending unit transmits a response signal to the response sending unit, the response sending unit calls the current position information of the GPS positioning unit after receiving the response signal, and sends the position information and the data sent by the sampling data uploading module to the area data input module.

By adopting the scheme, the position information can be automatically sent together when the staff sends the four-pest density information, and the operation of the staff is reduced.

The invention is further configured to: the storage module comprises a local storage unit and a cloud storage unit; the local storage unit stores the data in the local hard disk; and the cloud storage unit calls the data stored in the local storage unit and stores the data in the network cloud disk.

By adopting the scheme, the cloud storage unit can recover the data for the local storage unit when the data of the local storage unit is damaged or lost.

The invention is further configured to: the storage module further comprises a data deleting unit, wherein the data deleting unit detects the capacity of the local storage unit in real time, and when the capacity of the local storage unit exceeds ninety percent, the data deleting unit automatically deletes the data with the longest storage time according to the storage time until the capacity of the local storage unit is reduced to be less than seventy percent.

By adopting the scheme, the situation that the running speed of the system is influenced by excessive data stored in the local storage unit can be prevented.

The invention is further configured to: the drug delivery amount calculation module is internally stored with coefficients a, b, c and d and error values w, x, y and z which are input into the drug delivery amount calculation module in advance by workers according to the types of drugs, and the drug delivery amount calculation module calculates the drug delivery amounts of four pests of drugs according to the drug delivery amount of the mouse drugs = the density of the mouse x a + w, the drug delivery amount of the cockroach drugs = the density of the cockroach x b + x, the drug delivery amount of the fly drugs = the density of the fly x c + y, and the drug delivery amount of the mosquito drugs = the density of the mosquito x d + z.

By adopting the scheme, the calculation process of the dosage calculation module is simple, reasonable and easy to control.

An application method for regional four-pest quantity detection can automatically calculate the dosage of four-pest medicines and clearly and three-dimensionally display the dosage of the four-pest medicines in each region to workers, and the workers can conveniently and accurately put the medicines.

an application method for detecting regional four pests comprises the following steps:

firstly, detecting the four pest density of each area;

secondly, inputting the detected four pest density into a mobile phone APP;

thirdly, the mobile phone APP transmits the four pest density and the corresponding position information to the central control system for storage;

fourthly, the central control system calculates the dosage of the four pesticides in each area;

fifthly, filling the dosage of the four pesticides in each area into the three-dimensional map model of the divided area by the central control system;

sixthly, the central control system displays the three-dimensional map model to a worker, and the worker clicks the corresponding area to obtain the dosage of the four pesticides in the area;

and seventhly, the worker administers the medicine to the area according to the three-dimensional map model displayed by the central control system.

The invention is further configured to: the first step is specifically set as follows:

detecting the density of the mice in each area by using a visual rat mark method or a mouse sticking plate method; detecting the density of cockroaches in each area by using a cockroach sticking paper method; detecting the fly density of each area by using a visual inspection method or a fly sticking strip method; the mosquito density of each area was measured using a scoop-catch method.

By adopting the scheme, the method for detecting the density of the four pests by the conventional method is scientific and reasonable, and the detected data is accurate.

The invention is further configured to: the fourth step is specifically set as follows:

and the central control system calculates the dosage of the rodent drugs, the cockroach drugs, the flies and the mosquitoes in each area according to the pre-input coefficients a, b, c and d and the error values w, x, y and z.

By adopting the scheme, the coefficient and the error value which are input by the staff through control can control the calculation result according to the characteristics of the put medicine.

In conclusion, the invention has the following beneficial effects:

1. the working personnel detect the density of the four pests in each area, after the detection result is input into the mobile phone APP, the central control system automatically generates a three-dimensional map model with the dosage of the four pests medicines and displays the three-dimensional map model to the working personnel, and the working personnel dose the areas according to the three-dimensional map model displayed by the central control system, so that the working personnel can conveniently and accurately dose the medicines;

2. the position information can be automatically sent together when the staff sends the four-pest density information, so that the operation of the staff is reduced;

3. the calculation process of the drug dosage calculation module is simple, reasonable and easy to control.

Drawings

FIG. 1 is a block diagram of an overall system of a first embodiment;

FIG. 2 is a system block diagram of a central control system and a mobile phone APP in the first embodiment;

FIG. 3 is a system block diagram of an outstanding sample data upload module and a GPS location transmit module according to one embodiment;

FIG. 4 is a system block diagram of a highlighted memory module in one embodiment.

In the figure, 1, a mobile phone APP; 11. a sampled data uploading module; 111. a mouse density acquisition unit; 112. a cockroach density acquisition unit; 113. a fly density acquisition unit; 114. a mosquito density acquisition unit; 12. a GPS positioning and sending module; 121. a GPS positioning unit; 122. a response transmitting unit; 2. a central control system; 21. a region data input module; 22. a storage module; 221. a local storage unit; 222. a cloud storage unit; 223. a data deleting unit; 23. a region dividing module; 24. a regional three-dimensional graph building module; 25. a drug dosage calculation module; 26. a region data visualization module; 27. and a display module.

Detailed Description

The first embodiment is as follows: a regional four pest number detection system, as shown in figure 1, comprises a central control system 2 and a plurality of mobile phones APP1 installed in mobile phones of workers. The mobile phone APP1 is capable of data interaction with the central control system 2 via a mobile network.

As shown in fig. 2 and fig. 3, the mobile phone APP1 includes a sampling data uploading module 11 and a GPS positioning sending module 12, and the sampling data uploading module 11 includes a rat density acquisition unit 111, a cockroach density acquisition unit 112, a fly density acquisition unit 113, and a mosquito density acquisition unit 114. Detecting the density of the mice in the current area by a worker by adopting a visual mouse trace method or a mouse sticking plate method; the visual rat trace method estimates the density of the rats by observing rat traces such as rat holes, rat tunnels, rat feces and the like; the rat-sticking plate method is a method in which a rat density is estimated from the number of rats stuck on a rat-sticking plate after 24 hours by leaving the rat-sticking plate. The worker inputs the estimated density of the mouse into the mouse density collecting unit 111. Detecting the density of cockroaches in the current area by a worker through a cockroach sticking paper method; the cockroach-sticking paper method estimates the density of cockroaches by placing a cockroach-sticking paper and counting the number of cockroaches stuck to the cockroach-sticking paper after 24 hours. The worker inputs the estimated density of the cockroaches to the cockroach density collecting unit 112. The worker detects the fly density by a visual method or a fly sticking strip method; the visual inspection method estimates the fly density by observing and recording the number of adult flies in the visual field range by workers; the fly stick method estimates the fly density by placing fly sticks according to the number of flies stuck to the fly sticks after 24 hours. The worker inputs the fly density into the fly density collecting unit 113. Detecting the mosquito density by a worker through a spoon catching method; the scoop-catch method estimates the mosquito density by taking the water container of a residential area or the water of a peripheral river bank and checking the number of mosquito larvae or pupae therein. The worker inputs the mosquito density into the mosquito density acquisition unit 114.

As shown in fig. 2, the GPS positioning sending module 12 is connected to the GPS positioning function of the mobile phone of the staff, and the GPS positioning sending module 12 automatically obtains the current position information of the staff. The central control system 2 includes a region data input module 21, a storage module 22, a region division module 23, a region three-dimensional map creation module 24, a drug administration amount calculation module 25, a region data visualization module 26, and a display module 27. The sampling data uploading module 11 sends the rodent density, cockroach density, fly density and mosquito density input by the staff to the area data input module 21, and the GPS positioning sending module 12 sends the position information of the staff to the area data input module 21. The region data input module 21 integrates the received rodent density, cockroach density, fly density, mosquito density and position information together and transmits the integrated information to the storage module 22 for storage.

As shown in fig. 2 and 3, the GPS positioning module includes a GPS positioning unit 121 and a response transmitting unit 122. The GPS positioning unit 121 acquires current position information in real time. Whenever the sampling data uploading module 11 sends data to the area data input module 21, the sampling data uploading module 11 transmits a response signal to the response sending unit 122, the response sending unit 122 calls the current position information of the GPS positioning unit 121 after receiving the response signal, and sends the position information and the data sent by the sampling data uploading module 11 to the area data input module 21.

As shown in fig. 2 and 4, the storage module 22 includes a local storage unit 221, a cloud storage unit 222, and a data deletion unit 223. The local storage unit 221 is connected to the local hard disk, and the local storage unit 221 stores data in the local hard disk. The cloud storage unit 222 is connected to a network cloud disk, and whenever the local storage unit 221 stores new data, the local storage unit 221 synchronizes the new data to the cloud storage unit 222, and the cloud storage unit 222 stores the data in the network cloud disk. The local storage unit 221 may call the stored data from the cloud storage unit 222 for restoring the data within the local storage unit 221.

As shown in fig. 2 and 4, the data deleting unit 223 detects the capacity of the local storage unit 221 in real time, and when the capacity of the local storage unit 221 exceeds ninety percent, the data deleting unit 223 automatically deletes the data with the longest storage time according to the storage time until the capacity of the local storage unit 221 is reduced to less than seventy percent.

As shown in fig. 2, the regional three-dimensional map building module 24 is used for a worker to build a three-dimensional map model, and the worker creates the three-dimensional map model through software such as ACM Dream or obtains the three-dimensional map model of the region through a vendor such as google. The regional three-dimensional map building module 24 transmits the three-dimensional map model to the regional division module 23. The region division module 23 displays the three-dimensional map model to a worker, the worker divides the three-dimensional map model into a plurality of regions, and the region division module 23 transmits the three-dimensional map model after the regions are divided to the storage module 22 for storage.

As shown in fig. 2, when the drug needs to be administered, the administration amount calculation module 25 calls the murine density, the cockroach density, the fly density, and the mosquito density of the same region stored in the storage module 22 according to the position information, and the worker inputs coefficients a, b, c, and d and error values w, x, y, and z to the administration amount calculation module 25 in advance according to the type of the drug, wherein the administration amount of the murine drug = murine density × a + w; the cockroach medicament application amount = cockroach density × b + x; the dosage of the fly drug = fly density × c + y; the dosage of the mosquito drug = mosquito density × d + z. The drug delivery amount calculation module 25 transmits the obtained mouse drug delivery amount, cockroach drug delivery amount, fly drug delivery amount, mosquito drug delivery amount and position information of the region to the region data visualization module 26.

As shown in fig. 2, the area data visualization module 26 calls the three-dimensional map model stored in the storage module 22, and the area data visualization module 26 fills the received dosage of the rodent drug, the dosage of the cockroach drug, the dosage of the fly drug, and the dosage of the mosquito drug into the corresponding area in a text format according to the position information, so that a worker can pop up the corresponding dosage when clicking the corresponding area. The regional data visualization module 26 transmits the processed three-dimensional map model to the display module 27, and the display module 27 displays the three-dimensional map model to the staff. The worker can quickly know the specific dosage of the rodent drugs, the dosage of the cockroach drugs, the dosage of the fly drugs and the dosage of the mosquito drugs in different areas through the three-dimensional map model.

Example two: an application method for detecting regional four pests comprises the following specific steps:

firstly, detecting the density of the mice in each area by using a visual mouse tracking method or a mouse sticking plate method; detecting the density of cockroaches in each area by using a cockroach sticking paper method; detecting the fly density of each area by using a visual inspection method or a fly sticking strip method; the mosquito density of each area was measured using a scoop-catch method.

And secondly, inputting the mouse density, the cockroach density, the fly density and the mosquito density obtained through detection into the mobile phone APP 1.

And thirdly, the mobile phone APP1 transmits the rodent density, the cockroach density, the fly density, the mosquito density and the corresponding position information to the central control system 2 for storage.

And fourthly, the central control system 2 calculates the dosage of the mouse drugs, the dosage of the cockroach drugs, the dosage of the fly drugs and the dosage of the mosquito drugs in each area according to the pre-input coefficients a, b, c and d and the error values w, x, y and z.

And fifthly, filling the dosage of the rodent drugs, the dosage of the cockroach drugs, the dosage of the fly drugs and the dosage of the mosquito drugs in each area into the three-dimensional map model divided into the areas by the central control system 2.

And sixthly, the central control system 2 displays the three-dimensional map model to a worker, and the worker clicks the corresponding area to obtain the dosage of the rodent drug, the dosage of the cockroach drug, the dosage of the fly drug and the dosage of the mosquito drug in the area.

And seventhly, the staff dose the region according to the three-dimensional map model displayed by the central control system 2.

The embodiments of the present invention are preferred embodiments of the present invention, and the scope of the present invention is not limited by these embodiments, so: all equivalent changes made according to the structure, shape and principle of the invention are covered by the protection scope of the invention.

Claims

1. A regional four harmful quantity detecting system is characterized in that: the system comprises a central control system (2) and a plurality of mobile phones APP (1) installed in mobile phones of workers, wherein the mobile phones APP (1) comprise a sampling data uploading module (11) and a GPS positioning and sending module (12);

the sampling data uploading module (11) is used for the staff to input the detected four pest density information and send the density value of the four pest;

the GPS positioning and sending module (12) automatically acquires the current position information of the staff and sends the position information;

the central control system (2) comprises a region data input module (21), a storage module (22), a region dividing module (23), a region three-dimensional graph establishing module (24), a drug administration amount calculating module (25), a region data visualization module (26) and a display module (27);

the regional data input module (21) receives the density values of the four pests sent by the sampling data uploading module (11) and the position information sent by the GPS positioning sending module (12), and the regional data input module (21) integrates the received density values and the position information of the four pests into data information and outputs the data information;

the regional three-dimensional map building module (24) is used for building and outputting a three-dimensional map model by a worker;

the region division module (23) receives the three-dimensional map model output by the region three-dimensional map building module (24), a worker divides the region of the three-dimensional map model through the region division module (23), and the region division module (23) outputs the divided three-dimensional map model;

the storage module (22) receives the data information output by the region data input module (21) and the three-dimensional map model output by the region dividing module (23), and the storage module (22) stores the received data information and the three-dimensional map model;

the drug feeding amount calculation module (25) calls the data information stored by the storage module (22), calculates the drug feeding amount of the four pesticides in each region according to the data information, and outputs the drug feeding amount of the four pesticides and the position information of the corresponding region by the drug feeding amount calculation module (25);

the region data visualization module (26) receives the dosage of the four pesticides and the position information of the corresponding region output by the dosage calculation module (25), calls the three-dimensional map model stored by the storage module (22), fills the dosage of the four pesticides into the corresponding region of the three-dimensional map model according to the position information of the corresponding region, and outputs the processed three-dimensional map model by the region data visualization module (26);

the display module (27) receives and displays the three-dimensional map model output by the area data visualization module (26).

2. The regional pest number detection system of claim 1, wherein: the sampling data uploading module (11) comprises a mouse density acquisition unit (111), a cockroach density acquisition unit (112), a fly density acquisition unit (113) and a mosquito density acquisition unit (114); the staff inputs the estimated density of the mouse into a mouse density acquisition unit (111); the worker inputs the estimated density of the cockroaches into a cockroach density acquisition unit (112); the worker inputs the fly density into a fly density acquisition unit (113); the worker inputs the mosquito density into the mosquito density acquisition unit (114).

3. The regional pest number detection system of claim 2, wherein: detecting the density of the mice in the current area by a worker by adopting a visual mouse trace method or a mouse sticking plate method, and inputting the density of the mice into a mouse density acquisition unit (111);

the worker detects the density of the cockroaches in the current area by a cockroach sticking paper method and inputs the density of the cockroaches into a cockroach density acquisition unit (112);

the worker detects the fly density of the current area by a visual method or a fly sticking method and inputs the fly density into a fly density acquisition unit (113);

the worker detects the mosquito density of the current area through a spoon catching method and inputs the mosquito density into a mosquito density acquisition unit (114).

4. The regional pest number detection system of claim 1, wherein: the GPS positioning module comprises a GPS positioning unit (121) and a response sending unit (122);

the GPS positioning unit (121) acquires current position information in real time;

when the sampling data uploading module (11) sends data to the area data input module (21), the response sending unit (122) transmits a response signal to the sampling data uploading module (11), the response sending unit (122) calls the current position information of the GPS positioning unit (121) after receiving the response signal, and sends the position information and the data sent by the sampling data uploading module (11) to the area data input module (21).

5. The regional pest number detection system of claim 1, wherein: the storage module (22) comprises a local storage unit (221) and a cloud storage unit (222); the local storage unit (221) stores data in a local hard disk; the cloud storage unit (222) calls the data stored in the local storage unit (221) and stores the data into the network cloud disk.

6. The regional pest number detection system of claim 5, wherein: the storage module (22) further comprises a data deleting unit (223), wherein the data deleting unit (223) detects the capacity of the local storage unit (221) in real time, and when the capacity of the local storage unit (221) exceeds ninety percent, the data deleting unit (223) automatically deletes the data with the longest storage time according to the storage time until the capacity of the local storage unit (221) is reduced to be less than seventy percent.

7. The regional pest number detection system of claim 1, wherein: the drug delivery amount calculation module (25) is internally provided with a working person which inputs coefficients a, b, c and d and error values w, x, y and z into the drug delivery amount calculation module (25) in advance according to the types of drugs, and the drug delivery amount calculation module (25) calculates the drug delivery amounts of four pests of drugs according to the drug delivery amount of the mouse drugs = mouse density x a + w, cockroach drug delivery amount = cockroach density x b + x, fly drug delivery amount = fly density x c + y, and mosquito drug delivery amount = mosquito density x d + z.

8. A regional four-pest quantity detection application method is characterized by comprising the following steps:

firstly, detecting the four pest density of each area;

secondly, inputting the detected four pest density into a mobile phone APP (1);

thirdly, the mobile phone APP (1) transmits the four pest density and the corresponding position information to the central control system (2) for storage;

fourthly, the central control system (2) calculates the dosage of the four pesticides in each area;

fifthly, filling the dosage of the four pesticides in each area into the three-dimensional map model of the divided area by the central control system (2);

sixthly, the central control system (2) displays the three-dimensional map model to a worker, and the worker clicks the corresponding area to obtain the dosage of the four pesticides in the area;

and seventhly, the worker administers the medicine to the area according to the three-dimensional map model displayed by the central control system (2).

9. The regional four pest number detection application method of claim 8, wherein the step one is specifically configured as:

10. The regional four pest number detection application method according to claim 1, wherein the step four is specifically set as:

and the central control system (2) calculates the dosage of the rodent drugs, the dosage of the cockroach drugs, the dosage of the fly drugs and the dosage of the mosquito drugs in each area according to the pre-input coefficients a, b, c and d and the error values w, x, y and z.