Patent Publication Number: US-4647860-A

Title: Apparatus for automating standard voltage reference cell intercomparisons

Description:
BACKGROUND 
     Standard voltage reference cells (herein cells) regardless of the care used in production vary in voltage output when measured in the microvolt and nanovolt range. For applications requiring voltage accuracy and for use in standards labs groups of cells are intercompared to detect variances in voltage between the cells. 
     Under the Group Voltage Measurement Assurance Program sponsored by the National Bureau of Standards (NBS), individual cells in groups of four or six cells are intercompared with individual cells in other groups. By intercomparison is meant determining the voltage potential difference between two cells. NBS has recommended a method of intercomparing cells (see Eicke, Woodward G. and Auxier, Laurel M., Regional Maintenance of the Volt Using NBS Volt Transfer Techniques, IEEE TRANSACTIONS, Vol IM-23, No. 4, December 1974, pp. 290-294) by measuring the voltage difference between pairs of cells in a statistically balanced design. For instance, one possible design for comparing two groups of four cells is shown in Table I below: 
     
                       TABLE I                                                     
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NO.       A SIDE          B SIDE                                          
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1         Group 1, Cell 1 (vs)                                            
                          Group 2, Cell, 1                                
2         Group 1, Cell 1 (vs)                                            
                          Group 2, Cell, 3                                
3         Group 1, Cell 3 (vs)                                            
                          Group 2, Cell, 3                                
4         Group 1, Cell 3 (vs)                                            
                          Group 2, Cell, 1                                
5         Group 1, Cell 2 (vs)                                            
                          Group 2, Cell, 2                                
6         Group 1, Cell 2 (vs)                                            
                          Group 2, Cell, 4                                
7         Group 1, Cell 4 (vs)                                            
                          Group 2, Cell, 4                                
8         Group 1, Cell 4 (vs)                                            
                          Group 2, Cell, 2                                
9         Group 2, Cell 2 (vs)                                            
                          Group 1, Cell, 1                                
10        Group 2, Cell 2 (vs)                                            
                          Group 1, Cell, 3                                
11        Group 2, Cell 4 (vs)                                            
                          Group 1, Cell, 3                                
12        Group 2, Cell 4 (vs)                                            
                          Group 1, Cell, 1                                
13        Group 2, Cell 1 (vs)                                            
                          Group 1, Cell, 2                                
14        Group 2, Cell 1 (vs)                                            
                          Group 1, Cell, 4                                
15        Group 2, Cell 3 (vs)                                            
                          Group 1, Cell, 4                                
16        Group 2, Cell 3 (vs)                                            
                          Group 1, Cell, 2                                
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     As can be seen from Table I the eight cells (two groups of four) are compared using 16 measurements of voltage differences. Note also that each cell appears on the A side twice and on the B side twice. 
     When all cell comparisons are complete, a least squares fit of the values of the voltage difference between the cells can be computed. The values from the least squares fit can then be compared to the values measured and a standard deviation can be calculated. 
     Traditionally, voltage measurements between cells has been done by operators manually connecting cells together and detecting values. However, the amount of comparisons (e.g. 32 comparisons for comparing four groups of four cells), results in a great amount of time being spent by operators in performance of the cell measurements. Additionally, operator technique can affect the measured value resulting in different values being detected by different operators. Furthermore, there is a heightened danger of cell damage when measurement leads on cells are moved manually by operators. Commercially available cell scanners have proved to be either too expensive or not able to measure voltage values to sufficient levels of precision. 
     SUMMARY OF THE INVENTION 
     In accordance with the preferred embodiment of the present invention, an apparatus is presented for performing standard cell intercomparisons. A first terminal on each cell is coupled through a common line switch associated with that cell to a common line. A second terminal (opposite in polarity to the first terminal) on each cell is similarly coupled through an associated A switch to an A line and through an associated B switch to a B line. All switches are normally in the off (non-conducting) position. 
     When two cells are intercompared, the cells common line switches are both turned on, thus electrically coupling together the first terminals of the two cells. Additionally, the A switch on a first of the two cells is turned on coupling the second terminal of that cell to the A line. The B switch on the second of the two cells is then turned on coupling the second terminal of that cell to the B line. A potentiometer coupled to the A line and the B line detects the voltage difference between the A line and the B line to determine the voltage difference between the two cells. 
     Determining which two cells are to be intercompared may be done either manually by switches on the apparatus, or through interaction with a computing system. 
     Various mechanisms within the apparatus insure protection of the cells. These mechanisms include: encoding of selection information to insure only one cell for the A line and only one cell for the B line is selected; limiting the power available to switches so only one switch can be turned on within a given time span; inclusion of a protection line associated with the A line, and a protection line associated with the B line so that a logic control circuit can detect when a cell is coupled to the A line or the B line and prevent a second cell from being coupled to either the A line or the B line; and, requiring an operator to simultaneously depress two pushbuttons located on a front panel of the apparatus in order to select a cell to be coupled to either the A line or the B line. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows a front panel of a standard cell intercomparator in accordance with the preferred embodiment of the present invention. 
     FIG. 2 shows a plurality of cells coupled through switches to a potentiometer. 
     FIGS. 3A and 3B show schematics of a relay switch in accordance with the preferred embodiment of the present invention. 
     FIG. 4 shows a relay switch in accordance with the preferred embodiment of the present invention. 
     FIG. 5 shows a block diagram of a standard cell intercomparator in accordance with the preferred embodiment of the present invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     In FIG. 1, a front panel 104 of a standard cell intercomparator is shown. An opererator depresses a Line A pushbutton 101 or a line B pushbutton 102 simultaneously with a cell selection pushbutton from a series of cell selection pushbuttons 103 in order to select a standard cell. A pushbutton switch 105 when depressed restores control to pushbuttons 101, 102, 103 when cell selection was priorly done remotely by a computing system. 
     In FIG. 2, a cell 201, a cell 202 and a cell 203 are shown. Cell 201 is coupled to an A line 204 through a switch 211, and to a B line 205 through a switch 212. Similarly, cell 202 is coupled to A line 204 through a switch 221, and to B line 205 through a switch 222; and cell 203 is coupled to A line 204 through a switch 231, and to B line 205 throught a switch 232. Cell 201 is coupled to a common line 207 through a switch 214 and a switch 213; cell 202 is coupled to common line 207 through a switch 224 and a switch 223; and cell 203 is coupled to common line 207 through a switch 234 and a switch 233. Although FIG. 2 shows only cells 201-203, typically there are many more cells, e.g. 32, similarly coupled to A line 204, B line 205, and C line 207. 
     Unless an operator selects a certain cell to be coupled to A line 204 or B line 205, all switches are in the off, i.e., open position. In order to perform an intercomparison between cell 201 (on A line 204) and cell 202 (on B line 205), an operator would simultaneously depress pushbutton 101 and a pushbutton from the series of pushbuttons 103 that corresponds to cell 201. After releasing these pushbuttons, the operator would then simultaneously depress pushbutton 102 and a pushbutton from the series of pushbuttons 103 that corresponds to cell 202. A potentiometer 206 would then measure the voltage difference between A line 204 and B line 205 to complete the intercomparison. 
     In FIG. 2, switches 211-214, 221-224, and 231-234 are shown as being single-pole-single-throw switches. In the preferred embodiment--to protect against thermoelectric potentials--latching relays may be used, for instance a latching relay, part No. 12BW3LD manufactured by The PRINTACT Division of Executone Corporation having a place of business in Long Island City, N.Y. 11101. Additional design constraints to limit thermoelectric potentials include enclosure of switches 211--214, 221-224, and 231-234 in an isothermal container and the use of gold contacts throughout the apparatus. These design constraints reduce variations in thermoelectric voltage potentials to a level below a measurable range of variation in voltage potential across cells 201, 202, and 203. 
     FIG. 3A and FIG. 3B show how a switches 211 and 214 can be embodied by a relay switch. Switches 211 and 214 are shown within a relay switch 301. A node 307 is coupled to A line 204, a node 309 is coupled to cell 201, a node 313 is coupled to common line 207 and a node 311 is coupled to cell 201. 
     In FIG. 3A, relay 301 is shown in the &#34;off&#34; position, i.e. switches 211 and 214 are open (non-conducting). When switches 211 and 214 are open, a node 306 is coupled to a node 308 by a connector 304, and a node 312 is coupled to a node 310 by a connector 305. Nodes 306, 308, 310, and 312 may be used in a series protection line (see below). In FIG. 3B, relay 301 is shown in the &#34;on&#34; position, i.e. switches 211 and 214 are closed (conducting). When switches 211 and 214 are closed, node 307 is coupled to node 309 by a connector 364, and node 313 is coupled to node 311 by a connector 365. Thus when relay 301 is &#34;off&#34; cell 201 is not electrically connected to A line 204, and when relay 301 is &#34;on&#34; cell 201 is electrically connected to A line 204 and to common line 207. Similarly, relay switches may be used for switches 212-213, 221-224, and 231-234. 
     In FIG. 4 relay 301 is shown to be comprised of an encapsulated motor section 401, a magnetically pivoted swinger assembly 402 and a fixed contact section on a printed circuit board 403. 
     In FIG. 5, pushbuttons 103 are shown coupled to a 32 to 5 line encoder 502. The presence of encoder 502 insures that an operator can select only 1 cell at a time. 
     Pushbuttons 101 and 102 are shown coupled to a 2 to 1 encoder 503. Outputs from encoders 502 and 503 are coupled through a series of switches 507. Series of switches 507 comprises a series of gates 524-530 which act like single-pole-double-throw switches and which determine whether selection of cells is done by pushbuttons 101-103, or by inputs 504 from a bus interface 505. Series of switches 507 may be, for example, two Quadruple 2-line-to-1-line data selectors such as a part number SN74LS157 manufactured by Texas Instruments of Dallas, Tex. Inputs 504 may be inputs from a computer interface, for example, inputs formulated according to GP-IB interface bus standard IEEE-488. Gates 524-530 within series of switches 507 may be toggled by an input 506 from interface 505 or returned to frontpanel control by switch 105. 
     Outputs from series of switches 507 are coupled to a 6 to 64 line decoder 509 and to a logic control circuit 508. Decoder 509 includes circuits to drive 32 A line relay coils 513 and 32 B line relay coils 523. Relay coils 513 and 523 are found within relays such as relay 301 shown in FIGS. 3A, 3B and 4. An output from each relay coil in relay coils 513 and 523 is coupled through a resistance 511, typically 200 ohms, to a power source 510 typically set at 13 volts. A capacitance 512, typically 5 microfarads is shown coupled to resistance 511 and to a reference voltage (ground). Capacitance 512 limits the power available to relay coils 513 and 514 so that only one relay may be switched at a time. This protects cells from being misconnected by a malfunction in decoder 509. 
     Logic control circuit 508 is coupled to a series protection line 534 for A line 204 and to a series protection line 535 for B line 205. Series protection lines 534 and 535 are also coupled to a reference voltage (ground). A plurality of switches 520, a switch 521 and a plurality of switches 522 are switched by a relay. As described in the discussion of FIG. 3A, when a relay is &#34;off&#34;, its associated series protection line switch will be closed (conducting) and when a relay is &#34;on&#34;, its associated series protection line switch will be open (non-conducting). If any switch on series protection line 534 is open (in this case switch 521 is open) then circuit 508 will signal decoder 509 through an A line close gate 536, so that decoder 509 will not allow any more cells to be coupled to A line 204. Similarly, if any switch on series protection line 535 is open then circuit 508 will signal decoder 509 through a B line close gate 537, so that decoder 509 will not allow any more cells to be coupled to B line 205. 
     Series protection wires 534 and 535 may be coupled by outputs 514 and 515 respectively to series protection wires in other standard cell intercomparators, thus providing cell protection when a plurality of standard cell intercomparators are used together.