GB 50026-2020 English PDF
GB 50026: Historical versions
| Standard ID | USD | BUY PDF | Lead-Days | Standard Title (Description) | Status |
| GB 50026-2020 | 4699 | Add to Cart | 15 days | Standard for engineering surveying | Valid |
| GB 50026-2007 | 150 | Add to Cart | Auto, < 3 mins | Code for engineering surveying | Obsolete |
| GB 50026-1993 | RFQ | ASK | 3 days | Code for engineering surveying | Obsolete |
Basic data
Standard ID: GB 50026-2020 (GB50026-2020)Description (Translated English): Standard for engineering surveying
Sector / Industry: National Standard
Classification of Chinese Standard: P11
Classification of International Standard: 93.020
Word Count Estimation: 222,281
Date of Issue: 2020-11-10
Date of Implementation: 2021-06-01
Older Standard (superseded by this standard): GB 50026-2007
Quoted Standard: GB/T 50103; GB 50167; GB/T 50548; GB/T 13923; GB/T 17798; GB/T 20257.1; GB/T 20257.2; CH/T 9012; CH/T 6003; CH/T 8024; TB 10601; CH/Z 3005
Issuing agency(ies): Ministry of Housing and Urban-Rural Development of the People's Republic of China; State Administration for Market Regulation
Summary: This standard is applicable to general measurement work in the field of engineering construction. In engineering surveys, the median error should be used as the standard to measure the accuracy of surveying and mapping, and twice the median error should be used as the limit error. For projects with higher accuracy requirements, the observation accuracy can be evaluated according to the method in Appendix A. The area type of engineering survey should be divided into general area, urban construction area, industrial and mining area and water area. The measuring instruments used in engineering surveys shall be strengthened in use and management, corresponding rules and regulations shall be formulated, and verification shall be carried out according to the prescribed period. The software used should pass the test or verification. The measurement result data quoted in the project shall be checked. Engineering measurement shall meet this standard
GB 50026-2020: Standard for engineering surveying
---This is a DRAFT version for illustration, not a final translation. Full copy of true-PDF in English version (including equations, symbols, images, flow-chart, tables, and figures etc.) will be manually/carefully translated upon your order.1 General 1.0.1 This standard is formulated in order to unify the technical requirements of engineering survey, achieve advanced technology, economical and reasonable, and make engineering survey results meet the principles of reliable quality and safe application. 1.0.2 This standard is applicable to general measurement work in the field of engineering construction. 1.0.3 In engineering surveying, the medium error should be used as the standard for measuring the accuracy of surveying and mapping, and twice the medium error should be used as the limit error. For projects with high precision requirements, the observation precision can be evaluated according to the method in Appendix A. 1.0.4 The types of areas for engineering surveys should be divided into general areas, urban construction areas, industrial and mining areas, and water areas. 1.0.5 For measuring instruments used in engineering surveys, use management should be strengthened, corresponding rules and regulations should be formulated, and verification should be carried out according to the prescribed cycle. The software used should pass the test or verification. 1.0.6 Check the measurement result data quoted in the project. 1.0.7 In addition to complying with this standard, the engineering survey shall also comply with the current relevant national standards. 2 Terms, symbols and abbreviations 2.1 Terminology 2.1.1 Satellite positioning measurement satellite positioning The technology and method of using a satellite positioning receiver to receive multiple positioning satellite signals of a satellite navigation system to determine the position of a ground point is referred to as satellite positioning. 2.1.2 Satellite positioning control network satellite positioning control network The measurement control network established by using satellite positioning measurement technology and methods is referred to as satellite positioning control network or satellite positioning network. 2.1.3 real time kinematic control survey real time kinematic control survey A method for measuring and setting control points using carrier phase real-time dynamic differential measurement technology. 2.1.4 triangular network triangular network The measurement control network is composed of a series of connected triangles, and the observation elements are angle and distance. 2.1.5 triangular control network survey The method of determining the position of the control point by measuring the triangulation network is a general term for the previous triangulation measurement, trilateration measurement and edge angle network measurement. 2.1.6 2"class instrument 2"class instrument A goniometer with a nominal error of 2" in rounds of horizontal observations under a standard environment. 2.1.7 5mm class instrument 5mm class instrument When the ranging length is 1km, the distance measuring instrument calculated according to the nominal accuracy formula of ranging is 5mm in the ranging error. 2.1.8 free station measurement free station After arbitrarily setting up a station, measure the side lengths and angles to a small number of known points around, obtain the coordinates of the station according to the principle of corner resection, and then measure and set up other points. 2.1.9 GNSS-leveling The normal height of the point is obtained by using satellite positioning to fit the elevation measurement or using the refined results of the regional quasi-geoid. 2.1.10 paper topographic map A topographic map with paper or Mylar as its initial support. 2.1.11 deformation monitoring deformation monitoring The process of monitoring the shape or position change of the monitoring object and related influencing factors, determining the change characteristics of the monitoring object over time, and performing deformation analysis. 2.1.12 three dimensional laser scanning technology Non-contact active measurement technology that obtains various information such as the three-dimensional coordinates of the surface of the measured object and the intensity of reflected light by emitting laser light, mainly including ground three-dimensional laser scanning, vehicle three-dimensional laser scanning and airborne lidar scanning. 2.1.13 Point cloud point cloud Obtain massive point collections of target surface properties in three-dimensional space by means of measurement. 2.2 Symbols A - the fixed error of the main technical indicators of the satellite positioning measurement control network; a - nominal fixed error of the total station; B——The proportional error coefficient of the main technical indicators of the satellite positioning measurement control network, and the width of the tunnel excavation face; b - the nominal scale error coefficient of the total station; C—collimation difference; D——length of ranging side, length of satellite positioning elevation checking route, distance from RTK measuring base station to checking point, grid side length, measuring slant distance; Dg——the length of the ranging side on the Gaussian projection plane; DH——the length of the distance-measuring side reduced to the average elevation plane of the survey area; DP——horizontal distance of survey line; D0——reduced to the length of the ranging side on the reference ellipsoid; d——Basic average length, pile diameter, side length round-trip distance measurement is poor; DS05, DS1, DS3 - level of optical level; DSZ05, DSZ1, DSZ3 - automatic leveling optical level, digital level; fβ——the angular closure difference of the wire loop or the azimuth angle closure difference of the attached wire; H——Water depth, height of buildings (structures), height of columns, length of vertical part of installation measuring pipeline, height of bridge tower, buried depth of tunnel; Hm——the average elevation of the two ends of the ranging side; HP - the average height of the survey area; h—height difference, caisson height of building construction, buried depth of underground pipeline, tunnel height; hd—basic contour distance; hm—the height difference between the geoid in the survey area and the reference ellipsoid; i—the angle between the collimation axis of the level gauge and the axis of the vial, point number, side number, and triangle number; K - Atmospheric refraction coefficient; KM - correction factor; L——Length of leveling section or route, length of main axis of outer profile, length of crown block or crane track, total length of bridge, span diameter of bridge, length of embedded parts, length between two openings of tunnel excavation, tunnel length, collimation The length of the line, the front and rear distances from the monitoring body or monitoring section to the tunnel excavation face; l——horizontal distance from the measuring point to the pile in the line, the length of the transverse centerline in meters from the intersection point, and the width of the river (river, canyon) crossed by the bridge; M—the denominator of the surveying scale; Mw——Height difference full median error; M△—height difference accidental error, point error of check point; Mh - the height error of the digital elevation model; m - medium error; mD - error in ranging; mDi——The actual distance measurement error and the average distance measurement error of the i-th side; mH—the error in the plane position of the repeated exploration of the underground pipeline; mV—the error in the buried depth of repeated exploration of underground pipelines; mα——error in azimuth angle; mβ——error in angle measurement; mS - error in displacement; mg—the error in the angle of the fixed angle; N—the number of combined routes or closed loops, the number of asynchronous loops in the control network, the total number of closed loops and combined wires; n——Number of stations, sections, sides, baselines, the number of baselines in asynchronous rings or combined lines, the number of triangles, the number of spans of building structures, the number of closure differences of the circumference angles of stations, Number of checkpoints and height difference; P - prior right; Pi - the prior weight of the i-th side distance measurement; Q - weight coefficient; R - the average radius of curvature of the earth; RA——the radius of curvature of the reference ellipsoid intercepting the arc in the direction of the ranging side; Rm—the average radius of curvature of the midpoint of the ranging side on the reference ellipsoid; S—the side length, slant distance, the distance between two adjacent detail points, the distance from the turning point pile to the middle pile, and the slant distance corrected by meteorological and multiplication constants; T—the denominator of side length relative error; W——closing difference, full-length closing difference of asynchronous ring and loop line, full-length closing difference of asynchronous ring or combined line; WX——X coordinate component closure difference; WY—Y coordinate component closure error; WZ——Z coordinate component closure difference, limit difference of edge-pole condition free term; Wf, Wg, Wj, Wb——respectively the tolerances of the free terms of the azimuth angle condition, fixed angle condition, angle-pole condition, and edge (baseline) condition; Wr——the angular value limit difference between the observation angle and the calculation angle; ym—the average value of the abscissa of the two ends of the distance-measuring side; α—vertical angle, ground inclination angle, proportional coefficient; αz——the sum of the cotangent functions of the two bases at the two ends of the outer edge opposite to the pole; αf—the sum of the cotangent functions of the adjacent base angles on both sides of the radiating side connected to the pole in the midpoint polygon, the sum of the cotangent functions of the adjacent base angles on both sides of the inner radiating side in the quadrilateral, and the sum of the cotangent functions of the two outer radiating sides the difference of the cotangent functions of the adjacent base angles of the sides; δh——The height difference of opposite observation is relatively poor; δ1,2——the change value of the direction from station 1 to the observation direction of aiming point 2; μ——unit weight error; σ—the error in the baseline length; β——find the distance angle; △——The discrepancy value of the round-trip height difference of the survey section, the closure difference of the left and right corners of the traverse station observation, and the limit value of the poor adjustment value; △d—the length is poor; △h—the limit value of height difference; △H——Poor buried depth of concealed pipeline point detection; △Hi—the buried depth between the recheck point and the original point is relatively poor; △hi——the difference between the detection height and the model height; △S——horizontal position deviation of concealed pipeline point detection; △Si—the plane position deviation between the review point and the origin; △y——Increment of the abscissa of the two ends of the distance-measuring side; △α——Compensation error of compensation type automatic leveling instrument. 2.3 Abbreviations BDS BeiDou Navigation Satellite System CORS Continuously Operating Reference Station System Continuously Operating Reference Station System IMU Inertial Measurement Unit Inertial Measurement Unit PDOP Position Dilution of Precision spatial position precision factor POS Positioning and Orientation System Positioning and Orientation System RTD RealTime Differential real-time code differential RTK RealTime Kinematic real-time dynamics
