Patent Document

FIELD OF THE INVENTION  
       [0001]     The present invention relates to a geodetic electronic levelling instrument for plane surveying, applications. More particularly, the invention relates to a levelling rod (also known as a levelling staff) for automatically determining a collimated position used in combination with an electronic level. The levelling rod contains blocks of coded symbols arrayed in the longitudinal direction, each indicating a height at determined intervals.  
       BACKGROUND ART  
       [0002]     Various approaches have already been proposed to eliminate human operator reading errors and speed up the measurement process, and attempts have been made to develop machine-readable barcodes in different ways.  
         [0003]     For instance, patent document U.S. Pat. No. 5,572,009 discloses a method of encoding a barcode in which a BP type of Code is formed from a P code with a given length, and whose half-bits and whole bits are alternately provided with light and dark symbols.  
         [0004]     Patent document U.S. Pat. NO. 5,742,378 discloses a barcode levelling rod having an alignment of the first and second (and third) scale dark symbols, the alignment being made in order cyclically at a constant pitch along the length of the staff. The first and second symbols have their widths made variable in different cyclic periods, and the third symbol has a constant width.  
         [0005]     Patent documents U.S. Pat. No. 6,167,629 and U.S. Pat. No. 5,887,354 disclose levelling rods for electronic levelling, having a plurality of bar-shaped marks disposed adjacent to each other in a longitudinal direction along the levelling rod.  
         [0006]     For all the above-mentioned levelling barcode rods, in near distance measurement, the position of the collimated barcode portion can be estimated by detecting the width dimension of the bar symbols. The width dimension of the bar symbols in the longitudinal direction of the rod is represented by a plurality of integers. If the distance between the levelling rod and the electronic level becomes large, the image of each bar symbol on the image receiver becomes small. As a result, it is difficult to discriminate accurate dimensions of the bar symbols. To this end, one plurality of barcodes disclosed in U.S. Pat. No. 5,572,009, U.S. Pat. No. 6,167,629 and U.S. Pat. No. 5,887,354 should be interpreted as two permutations of integers for near and remote distances. In these cases, the estimation of the position of the collimated portion is very coarse. It still requires a considerable amount of cross-correlation computation in a large size domain to determine the accurate position. For U.S. Pat. No. 5,742,378, FFT (Fast Fourier Transform) is used to calculate the distance between the rod and the electronic level in the remote distance measurement. Also, the height of the collimated portion is estimated by the detection of the phase angle of two periodic bar symbols. To obtain the accurate position, cross-correlation computation calculation is needed too.  
         [0007]     Current barcodes for electronic levelling are monochrome. In the above-mentioned barcodes, the height readings are encoded by the dimension of the bars or spaces between the bars. Therefore, with current monochrome barcode scales, there are disadvantages in that it is very difficult to estimate the position (height and distance) of the collimated portion on the levelling rod with a simple decoding algorithm and a small number of calculation steps.  
       SUMMARY OF THE INVENTION WITH OBJECTS  
       [0008]     According to a first aspect, the invention provides a levelling rod for a level determining apparatus, the rod having position indications therealong along expressed by barcode symbols,  
         [0009]     characterized in that at least some of the barcode symbols are colour barcode symbols, the colour serving to encode the position indications.  
         [0010]     In the preferred embodiment, the barcode symbols are organized in first and second blocks of barcode symbols, each providing a position indication; the length occupied along the rod by a first block is smaller than the length occupied along the rod by a second block, the first blocks thereby providing a finer position indication than the second blocks.  
         [0011]     The first blocks of barcode symbols can be formed of monochrome and colour bar code symbols.  
         [0012]     The first blocks can comprise just one colour barcode symbol and at least one monochrome barcode symbol.  
         [0013]     The second blocks can be formed purely of colour barcode symbols.  
         [0014]     The colour barcode symbols forming the second blocks can be colour barcode symbols which also serve to form the first blocks.  
         [0015]     A second block can be formed by one colour barcode symbol from of each of a plurality of first blocks.  
         [0016]     The colour barcode symbols can have a plurality of width values, and the second blocks can be formed only of colour barcode symbols having a relatively large width value.  
         [0017]     In the preferred embodiment, any three consecutive colour barcode symbols having the relatively large width value constitute a second block.  
         [0018]     The colour barcode symbols can have two possible width values.  
         [0019]     The pitch between consecutive the first blocks can be constant.  
         [0020]     Each second block can be comprised of just three colour barcode symbols.  
         [0021]     Each second block preferably has a unique colour sequence or permutation of colour barcode symbols.  
         [0022]     Adjacent the barcode symbols can be separated by a selected pitch value from a set of four different fixed pitch values.  
         [0023]     Any four adjacent barcode symbols can constitute a first block, the barcode symbols then forming an uninterrupted sequence of barcode symbols along the levelling rod.  
         [0024]     A first block can be comprised of three monochrome barcode symbols and one colour barcode symbol.  
         [0025]     The width dimensions of the monochrome barcode symbols can be chosen from a predetermined set of width values {w x  | subscript x=1,2,3,4 . . . }.  
         [0026]     Each first block can have a unique sequence of barcode symbols in terms of colour, width and pitch between adjacent barcode symbols.  
         [0027]     Each first block and/or second block preferably defines a unique pattern with respect to a block at any other portion of the levelling rod or an inversion thereof, thereby providing an indication, detectable by the level determining apparatus, of whether the rod is normally positioned or positioned with a top-down inversion.  
         [0028]     Advantageously, the colours of the colour barcode symbols are selected from the subtractive colour set: Magenta, Cyan, Yellow, or the colour set Red, Green, Blue, to enable the maximum degree of colour recognition.  
         [0029]     Barcode symbols can be differentiated from each other by their colours and/or widths, and barcode blocks can be differentiated from each other by their permutation of the colours of their bar symbols, the permutation of the width of bar symbols and the sequence of the pitches between their bar symbols.  
         [0030]     The length of each first block is preferably a constant value, and the length of each second block is preferably of a larger constant value.  
         [0031]     The pitches between the colour barcode symbols of the second block can be chosen from a set of integral multiples of the length of the first block, such that by virtue of the overlapping modulations of the pitches, the frequency lines appearing in a Fourier analysis of the combined pitches are enhanced.  
         [0032]     The colour barcode symbol comprised in a first block can further provide and indication of the “begin” and the “end” of that block.  
         [0033]     The first blocks are preferably dimensioned so as to be discriminated by a level determining apparatus located within and up to a predetermined distance, and the second blocks are preferably dimensioned so as to be discriminated by a the level determining apparatus located beyond the predetermined distance.  
         [0034]     According to a second aspect, the invention relates to the us of the levelling rod according to the first aspect for obtaining a height information, wherein the levelling rod is positioned substantially in a vertical plane, whereby the relative positions of the bars express a height value.  
         [0035]     According to a third aspect, the invention relates to a level determining apparatus specifically adapted for use with the levelling rod according to the first aspect, comprising:  
         [0036]     imaging means for obtaining a colour image of a portion of the levelling rod located a distance therefrom,  
         [0037]     processing means for identifying the position of the imaged portion along the levelling rod on the basis of colour information produced by the barcode symbols.  
         [0038]     The processing means can be operative to identify the position of the imaged portion selectively from a first block or from a second block within the imaged portion.  
         [0039]     In a preferred embodiment:  
         [0040]     the imaging means comprises a colour image sensor to receive the colour barcode image; and the processing means comprise:  
         [0041]     a symbol/pattern detection portion for detecting the colours, the pitches and an array bar symbol of the levelling rod;  
         [0042]     a memory portion for storing the sequence of colours of the bar symbols, the sequence of the widths of bar symbols and the corresponding sequence of the pitches between the bar symbols; and  
         [0043]     a computation portion for obtaining the position information of the collimated portion on the levelling rod, based on comparing a detected signal from the symbol detecting portion with the sequence of the bar symbols in the memory portion to find out a match.  
         [0044]     The apparatus can further comprise means for operating selectively between a first mode in which the barcode information from an imaged first block is read, and a second mode in which the barcode information from an imaged second block is read, the read information being delivered as a reading; the means can then be operative to read the information in the first mode when the imaged first block is readable, and to read the information in the second mode when the imaged first block is unreadable.  
         [0045]     The level determining apparatus can further comprise:  
         [0046]     means for storing the actual length, along the levelling rod of a first block and/or the actual length, along the levelling rod, of a second block,  
         [0047]     means for determining the length of the image of an imaged first block and/or the length of the image of an imaged second block,  
         [0048]     means for storing the value of the focal length of the optical system used to produce the imaged first and/or second blocks,  
         [0049]     means for determining a distance of the imaged levelling rod from the level determining apparatus on the basis of the actual length value(s), the imaged lengths and the focal length.  
         [0050]     According to a fourth aspect, the invention relates to a method of level determination specifically adapted for use with the levelling rod according to the first aspect, comprising the steps of:  
         [0051]     obtaining a colour image of a portion of the levelling rod;  
         [0052]     identifying the relative position of the imaged portion along the levelling rod by reading the colour information therein expressed by an imaged first block or by an imaged second block.  
         [0053]     The method can further comprise the steps of performing the identifying step selectively in accordance with a first mode in which the barcode information from an imaged first block is read, and a second mode in which the barcode information from an imaged second block is read, the read information being delivered as a reading,  
         [0054]     and of producing the reading in the first mode when the imaged first block is readable, and of producing the reading in the second mode when the imaged first block is unreadable.  
         [0055]     An objective of the preferred embodiment is to provide a method for using colours to encode a barcode scale for electronic levelling, so that the colour barcode scale can be used for discrimination of different measurement distances by means of a simple decoding algorithm resulting in fast measurement speed.  
         [0056]     Another objective of the preferred embodiment is to provide a colour barcode scale for accurate electronic levelling at different measurement distances.  
         [0057]     Yet another objective of the preferred embodiment is to provide a colour barcode that can be decoded using a simple decoding algorithm that reduces the calculation effort required.  
         [0058]     In one embodiment, the levelling rod has blocks of colour bar symbols disposed adjacent to each other in longitudinal direction along the levelling rod, where the colour barcode scale comprises of 2 sizes of colour barcode blocks; small barcode blocks are embedded into big ones; any four adjacent bar symbols constitute a smallest barcode block, in which 3 symbols are black and one symbol is in colour; the width dimensions of the 3 black bar symbols within one smallest barcode block are varied; the width of the colour bar symbol has two values: a wide value and a narrow value; the bar symbols are alternately arranged at 4 constant pitches; each big colour barcode block comprises of 3 adjacent wide colour bar symbols, which are chosen from the colour bar symbols within the smallest barcode blocks; the colours for the colour bar symbols are chosen from a subtractive colour set (Magenta, Cyan, Yellow); within one large colour barcode block, pitches between the two wide colour symbols are varied; any one colour barcode block is different from one colour barcode block chosen from any other portion of barcode on the levelling rod; any one colour barcode block is different from one colour barcode block chosen from any other portion of barcode on the inverted levelling rod.  
         [0059]     With colour printing and colour recognition now becoming more prevalent and inexpensive, using colour information in a barcode symbology is realistic and advantageous owing to the colour information. When used appropriately, it aids in increasing the information density of the barcode, allows for fast decoding and confers flexibility in barcode design.  
         [0060]     In a short distance measurement, at least one barcode block is within the field of view (FOV) of the electronic level. All the symbols within the FOV can be discriminated to determine the position of the collimated portion. At more remote distances, small bar symbols can no longer be resolved in a definite manner owing to the small pitches between the black bars and limited resolution of electronic level. Conversely, for a longer distance, larger barcode blocks are provided with their colours and large pitches adapted for discrimination at those larger distances. The characteristics of two-size barcode blocks simplify the position discrimination at different distances. Further, the fact that any one colour barcode block is different from any colour barcode block chosen from any other portion of barcode on the erected or inverted levelling rod enables the electronic level to determine automatically whether the levelling rod is erected correctly or inverted.  
         [0061]     In a preferred embodiment, the electronic level used in combination with the levelling rod comprises a colour symbol detection portion for detecting blocks of colour bar symbols on the levelling rod; a memory portion for storing bar block information in advance; and a computation portion for comparing the detected symbol signals on the receiver with a stock of the blocks of colour symbol in the memory, to obtain the position information. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0062]     The invention shall be more fully understood, and its advantages shall become apparent, from reading the following detailed description of the preferred embodiments, given purely non-limiting examples with reference to the appended drawings in which:  
         [0063]      FIG. 1  is a schematic view showing an arrangement of a colour barcode levelling rod and an electronic level at different (long, short) measurement distance, according to a preferred embodiment of the invention;  
         [0064]      FIG. 2  is an explanatory view diagram showing one example of the constitution of colour block barcode levelling scale according to a preferred embodiment of the invention;  
         [0065]      FIG. 3  is a block diagram showing a basic structure of the electronic level with colour image sensor according to a preferred embodiment of the invention; and  
         [0066]      FIG. 4  is diagram showing the signal processing procedure of an electronic level for the colour barcode level rod according to a preferred embodiment of the invention. 
     
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS  
       [0067]     The levelling system according to the preferred embodiment comprises a levelling rod (also referred to as a “staff”)  1  and an electronic level  2  as shown in  FIG. 1  through  FIG. 3 . In  FIG. 1 , reference number  1  denotes a levelling rod according to a preferred embodiment. The term “rod” generally designates any elongate physical support on which the symbols described below can be implemented. In use, the levelling rod  1  is collimated by an electronic level  2  in order to measure the height “h” of the collimated position along the rod. The rod is provided with colour barcode blocks  11  and  12  disposed along the longitudinal direction of the levelling rod. Reference numbers  11  and  12  respectively designate a relatively large colour barcode block and a relatively small colour barcode block. The term colour barcode block (or colour block) refers to a block of bar code symbols of which at least one symbol (bar) is in colour.  
         [0068]     Height information along the rod is expressed by a block of at least two adjacent bar code symbols, hereafter referred to as a “bar block” or simply “block”, the information being expressed, for a given block, by the set of data encoded by the bars, as explained below. The height information along the rod is expressed by the relative positions of the bar blocks along the length (longitudinal) direction of the rod or staff, with respect to an end portion of the latter, in a manner analogous to successive numbers marked at unit intervals on a measuring rule.  
         [0069]     A small colour barcode block  12  comprises of 3 adjacent black bar symbols and one colour bar symbol, which are arranged at any of 4 possible different fixed (preset) pitch values. Within a small barcode block, a permutation of any 3 adjacent black bar widths, which are chosen from a predetermined set of width values, the set {w x  | subscript x=1,2,3,4 . . . }, can determine a specific height reading. The width dimension of the colour barcode symbol within a small barcode block has one of two possible values: a wide width value, designated “w c1 ,” and a narrow width value, designated “w c2 ”. The possible colours of the colour bar symbol are chosen from a subtractive colour set: Magenta, Cyan and Yellow for maximum separation between the hue, or from its complementary (Red, Green and Blue). The length of a small colour barcode block is a constant value “L s ”.  
         [0070]     A large colour barcode block  11  consists of 3 adjacent wide colour barcode symbols. The pitches “L(x)” and “L b -L(x)” between two colour barcode symbols within one large colour barcode block are variable quantities. The length of a large colour barcode block is a constant value “L b ”.  
         [0071]     The electronic level  2  comprises of a telescope with automatic optical tilt compensator and focusing mechanism  21 , colour image sensor  22 , an eyepiece and reticle  23 , a processing unit  24  comprising a microprocessor with A/D (analog-to-digital converter), RAM type memory and ROM type memory, a beam splitter  25 , a display (liquid crystal display)  26 , and a keypad  27 , as shown in  FIG. 3 . Numeric readings are printed on the back of the levelling rod  1  in correspondence with the height indications given by the blocks, so that an operator can read the height values with his own eyes through the eyepiece and reticle  23 .  
         [0072]     As shown in  FIG. 3 , the electronic level  2  is provided with a telescope having an automatic optical compensator and focusing mechanism  21 . A received image of the levelling rod  1  is split by a beam splitter  25  and sent to the colour image sensor  22 . The colour image sensor  22  converts the optically received image of the levelling rod into a corresponding electrical signal, which it outputs into the processing unit  24 . The electrical image signal is converted into a digital signal by the A/D converter and stored in the RAM. The processing unit  24  recognizes the colours of the barcode symbols. For a large colour barcode block, the processing unit  24  detects the pitches between the colour symbols, and determines the corresponding bar blocks. For a small colour barcode block, the processing unit  24  detects the width of each symbol, and determines the corresponding bar blocks. The processing unit  24  determines the height “h” of the collimated position by comparing bar blocks with table values stored beforehand in the ROM. The collimation optical system comprises the telescope with automatic optical compensator and focusing mechanism  21 , beam splitter  25 , eyepiece and reticle  23 . The imaging optical system includes the telescope with automatic optical compensator and focusing mechanism  21 , and beam splitter  25  and colour image sensor  22 . The optical axis of the image optical system and the optical axis of the collimation optical system are arranged to coincide with each other, so that the collimation position on the levelling rod  1  and the collimated position in the image optical system coincide with each other.  
         [0073]     As shown in  FIG. 2 , the bar symbols within a small colour barcode block  12  on the levelling rod  1  are arranged at four constant pitches. Any set of 4 adjacent bar symbols, which includes 3 black symbols and one colour symbol, constitutes a small colour bar block. The colours for the colour barcode symbols are chosen from a subtractive colour set: Magenta, Cyan, Yellow; the width dimension for a colour bar symbol has two possible values:—a large value designated w c1  and a small value designated w c2 .  
         [0074]     A small colour barcode block is the minimum unit for encoding height readings. The widths of the black bar symbols are chosen from a predetermined set of width values, identified by the set {w x  | subscript x=1,2,3,4 . . . }. The sequence of the bar symbols is arranged such that any one permutation of 4 adjacent bar symbols selected from the colour barcode scale, is different from any permutation of 4 adjacent bar symbols extracted from any other portion of the levelling rod.  
         [0075]     The bar symbols within a large colour barcode block  11  on the levelling rod  1  comprise 3 adjacent wide colour bar symbols. The spacings “L(x)” and “L b -L(x)” between the wide colour bar symbols are variable. Any one colour barcode block on the levelling rod is different any other colour barcode block chosen from any other portion of the barcode scale on the erected or inverted levelling rod. Blocks of colour coded height markings are provided at unit intervals on a levelling rod to digitally indicate heights.  
         [0076]     By virtue of the introduction of two-size colour barcode blocks, decoding can be carried our simply and efficiently at different measurement distances. Decoding means are coupled to the output of the aforementioned detector for decoding the imaged coded mark to form a digital height signal. As shown in  FIG. 1 , at short distance “d 1 ”, there are only one or several small colour barcode blocks  12  within the field of view (FOV)  3  of the electronic level  2 . For small colour barcode blocks  12  within the FOV  3 , the colours and widths of the bar symbols, and the pitches between bar symbols can be discriminated at the short distance “d 1 ”. Then, the position of the collimated portion on the levelling rod can be determined by the discriminated small colour barcode blocks  12 . Referring to  FIG. 3 , at a long distance “d 2 ”, owing to the limited resolution of the electronic level  2 , the widths of the bar symbols within the FOV  3 , and even the colours for small colour bar symbols, may be too small or blurred to be differentiated from each other. In such cases, the large colour barcode block is recognized by discriminating the colours of the wide colour bar symbols and the pitches between the wide colour bar symbols. Then, the position of the collimated portion can be determined. The colours are selected from the subtractive colour set, because the subtractive colours have the maximum degree of recognition in the colour space. After the initial positioning of the collimated portion with the estimated values for height “h” and distance “d 1 ” or “d 2 ”, the microprocessor  24  will seek the exact value for height “h” of the collimated position and distance between the levelling rod  1  and the electronic level  2  in a refined search range through a cross-correlation evaluation between the detected image of barcode levelling rod  1  and the stored reference barcode in the ROM. The measurement results are displayed on the display  26 . This data processing procedure is shown in the flow chart of  FIG. 4 .  
         [0077]     The procedure begins with a pre-processing step S 2  during which the image data is acquired and organized in digital form. This step is followed by a colour recognition step S 4 , in which the colour bar symbols of the collimated image are identified in terms of their elementary colours (magenta, cyan, yellow).  
         [0078]     Next, the procedure seeks to determine (step S 6 ) whether or not the collimated bar code block is a large barcode block  11  (cf.  FIG. 2 ).  
         [0079]     If the collimated image does not contain a large barcode block  11 , then the procedure seeks to determine (step S 8 ) whether it comprises a small barcode block  12 , i.e. to determine whether it has an intelligible image signal for decoding a small barcode block. In the negative, the system determines that the levelling rod is out of target or range (step S 10 ) and proceeds to a results display step (step S 12 ) to indicate that situation.  
         [0080]     If the collimated image comprises a determined barcode block, whether it is a large barcode block  11  from step S 6 , or a small barcode block  12  from step S 8 , the system proceeds to carry out an estimate of the position of the collimated portion, to determine the height measurement (step S 14 ). The system then proceeds, if needs be, to a cross-correlation seek determination (step S 16 ), as explained further below.  
         [0081]     Since any one colour barcode block is different from any one colour barcode chosen from any other portion of the colour barcode scale on the erected or inverted levelling rod, whether the rod is erected or inverted can be automatically recognized by discriminating the permutation of the widths of bar symbols, and/or the pitches between the bar symbols, and/or the colours of bar symbols, at different measurement distance.  
         [0082]     On the basis of the focal length f of the telescope objective and detected constant length L s  for small colour barcode blocks, or the constant length L b  for large colour barcode blocks, the distance between the levelling rod  1  and electronic level  2  can be estimated by the equation 
 
 d   1   =f ( L   s   /m   1 ) or  d   2   =f ( L   b   /m   2 )   (2) 
 
         [0083]     where m 1  and m 2  are the corresponding image lengths on the focal plane for the constant block length L s  and L b .

Technology Category: 3