US1107503A - Telemeter. - Google Patents
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- US1107503A US1107503A US76337513A US1913763375A US1107503A US 1107503 A US1107503 A US 1107503A US 76337513 A US76337513 A US 76337513A US 1913763375 A US1913763375 A US 1913763375A US 1107503 A US1107503 A US 1107503A
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C3/00—Measuring distances in line of sight; Optical rangefinders
- G01C3/02—Details
Definitions
- present invention relates to horizon- 1 tclcmcters, in which the base-line emwhen ranges are being taken, beto the instrument.
- the whole instrument is rotated in about an axis parallel to the base-line, that the direction of the emerging rays direction of inspection) is altered with. the direction of the entering and by the same angle as the latter.
- 1 new telemeter the direction of in section is fixed and only the direction of e entering rays is variable in elevation. this purpose the two objective reflectsystems are jointly pane perpendicular to the base-line.
- a compensating reflecting m is disposed behind these systems and coupled to them in such a manner that it rotates through half as great an angle as the said systems. This may be effected by means o't' gearing or other well-known coupling means.
- the alteration in the posit-ion ot the images presented to the observer, which is to be obviated by the said compensating system, consists in a displacement of these images each in its plane such displacement being perpendicular to the base-line,
- so tar as an intermediate reflecting systcm is jointly rotatable with the two objective reflecting systems, which permits the axial rays to emerge in a direction perpendicular to the base-line.
- the two objective reflecting systems are jointly rotatable, or when the intermediate reflecting system, while it. participates in the rotation, permits the. axial rays to emerge in he direction oi the base-line, the alteration the position or the images presented to observer, which is to be obviated, conin a IT tation of these images each in plane.
- the compensating system to obviate such a rotation of the images coincidence telcmcter, i. e.
- the compensating system must be disposed in such a place that besides the said rotation of the single images a rotation of the line of coincidence in the plane of the images is also obviated; there fore, when the separating prism system is jointly rotatable with the objective reflecting systems, the compensating system must lie behind it, otherwise in front of it.
- compensating system of a stereoscopic telem- 5 eter must consist of two part-systems, through each of which passes one of the two systems of ray-pencils coming from the objectives; the same holds good for the.
- the compensating system of a coincidence telem eter when the said system lies in front of the separating prism system.
- the possibility of losing the adjustment of the instrument, when the objective reflecting systems are rotated, is lessened, by letting the intermediate reflecting system take part in the joint rotation of the two objective reflecting systems.
- the construction of the lnstru- 'ment is simplified, when the compensating system is disposed behind the intermediate reflecting system; in thiscase it must be rotatable about an axis parallel to the baseline and in the same sense as the objective reflecting systems. If the intermediate reflecting system be then formed in such a manner that it will permit the axial ray to emerge in the direction of the base-line and at some distance from the axis of rotation of the objective reflecting systems, gearing.
- the compensating system consists of two system-- parts disposed one behind the other, which each deflect the axial ray by 90 in one and the same plane and the front one of which is guided in the direction of the axial ray passing from it to the rear system-part, and when the front systempart is connected with the intermediate refleeting system so as to be rotatable about the axial ray emerging from the latter, the compensating system rotates during a rotation of the objective reflecting systems in the same sense as the latter and through half as great an angle.
- Figures 1 to 3 show the optical system of a stereoscopic telemeter according to the present invention.
- Fig. 1 in which the eye-lenses of the oculars are not shown, being a plan view with the objective reflecting systems so disposed as to permit the rays to enter the instrument in a horizontal direction
- Fig. 2 a corresponding section on line 2-2 of Fig. l
- Fig. 3 a similar section, belonging, however, to such a position of the objective reflecting systems that the rays entering the instrument are inclined downward.
- Figs. 1 in which the eye-lenses of the oculars are not shown, being a plan view with the objective reflecting systems so disposed as to permit the rays to enter the instrument in a horizontal direction
- Fig. 2 a corresponding section on line 2-2 of Fig. l
- Fig. 3 a similar section, belonging, however, to such a position of the objective reflecting systems that the rays entering the instrument are inclined downward.
- a to 7 are views of a constructional example of the telemeter according to the present invention, showing a coincidence telemeter, in the image-field of which the single image lying below the line of coincidence is inverted.
- Fig. 4 is an elevation partly in section along line Jr-*4: of Fig. 5
- Fig. 5 a plan view, also partly in section, along line 55 of Fig. 4:
- Figs. 6 and 7 crosssections on line 66 of Fig. 5.
- Fig. 6 corresponds to the position of the movable parts as shown in Figs. 4 and 5, where the rays enter the instrument in the horizontal direction
- Fig. 7 shows the same parts disposed for a vertical entrance of the rays.
- Fig. 1 behind the two optical squares a a which in this case form the objective reflecting systems, the objective lenses 6 are disposed.
- Two reflectors 0 form an intermediate reflecting system, which allows the axial rays to emerge in a direction perpendicular to the base-line.
- Each ocular is formed as an angled ocular with the aid of a mirror cl lying between the field-lens e and the eye-lens c and having its reflecting surface parallel to the base line and contains in the front focal plane a measuring mark system 6. All parts lying in front of the reflectors d are assumed to be rotatable jointly with the objective reflecting systems, while the two reflectors 0?
- the compensating system are to be jointly rotatable and the eye-lenses 6 which allow the rays to emerge in an inclined direction, are to be rigidly connected with the carrier of the telemcter.
- a straight line A A lying in the common reflecting plane of the reflectors d is assumed as the axis of rotation of the parts, which are jointly rotatable with the objective reflecting systems.
- the reflectors (Z are to be also rotatable about the same axis, provision being made, e. g. by suitably disposed gearing, for these reflectors to rotate in the same sense and through half as great an angle as the objective reflecting systems.
- the two pentagonal prisms a which form the objective reflecting systems, and the objective lenses 6 lying behind them are rigidly fixed to a tube f which is journaled in a casing f in such a manner that it can be rotated about its axis by means of a handle f".
- a pivot f on this casing serves for inserting the instrument in a tripod head.
- a glass wedge 9 gearing g for displacing the said wedge in the axial direction of the tube f and a scale g behind a window g indicate the measuring device.
- the separating prism system it, 72?, h in which the upper half of the cement layer between it and k is replaced by a separating layer it", which is reflecting on both sides, lets the axial ray emerge in the direction of the base-line and is also rigidly fixed to the tube f so as to be rotatable jointly with the objective reflecting systems.
- the mixed ray-pencil system emerging from the separating prism system in the direction of the base-line is received by a collective lens t and is transmitted by means of a reversing lens system, between the two members 2' and i of which the rays forming a pencil are parallel to one another, and three simple reflecting prisms k, k and la each of which deflects by 90, to the ocular system 6 6 from which the axial ray emerges in an upwardly inclined direction.
- the two prisms and 70 which deflect the axial ray in one and the same plane and in the same sense, form in this case the compensating system.
- the prismlc which forms the front system-part can slide by means of a hole in its mounting Z on a pin on, which is fixed to the mounting Z of the prism 70 forming the rear system-part, so that the prism k is guided in the direction of the axial ray pass- I ing from it to the prism 70
- the prism mounting Z is journaled in a bearing 12 fixed to the casing f the axis of which bearing coincides with the axial ray emerging from the prism It, so that the compensating system is rotatable about the axial ray emerging from it. Its axis of rotation and the axial ray emerging from the separating prism system are equidistant from the axis of the tube P.
- the compensating system For coupling the compensating system with the objective reflecting systems there is fixed to the tube f a hearing m in which the prism mounting Z is rotatable, and the axis of which coincides with the axial ray emerging from the separating prism system.
- the prism 7&1 slides on its guide and the compensating system rotates through an ed to maintain a fixed direction during such rotation, two objective systems disposed behind the said objective reflecting systems, an intermediate reflecting system and a compensating reflecting system, these two latter systems being also disposed behind the said objective reflecting systems, a measuring device and means for coupling the said ob jective reflecting systems and the said compensating system, these means being adapted to transmit half the rotation of the objective reflecting systems to the compensat ing system.
- Horizontal telemeter comprising an ocular system, two objective reflecting systems, means for rotating the said objective reflecting systems jointly about an axis parallel to the base-line, the axis of emergence of the said ocular system being adapted to maintain a fixed direction during such rotation, two objective systems disposed behind the said objective reflecting systems, an intermediate reflecting system disposed behind the said objective reflecting systems and adapted to rot-ate about an axis parallel to the base-line through the same angle and in the same sense as the latter systems,
- a compensating reflecting system dispoflcil behind the said intermediate system and adapted to rotate about an axis parallel to the base-line and in the same sense as the said other reflecting systems, a measuring device and means for coupling the said objective reflecting systems and the said com;
- pensating svstem these means being adapted to transmit half the rotation of the objective reflecting systems to the compensating system.
- Horizontal telemeter comprising an ocular system, two objective reflecting systems, means for rotating the said objective reflecting systems jointly about an axis parallel to the base-line, the axis of emergence of the said ocular system being adapted to maintain a fixed direction during such rotation, a measuring device, two objective systems disposed behind the said objective reflecting systems, an intermediate reflecting system disposed behind the said objective reflecting systems and adapted to rotate about an axis parallel to the base-line through the same angle and in the same sense as the latter systems and to let the axial ray emerge in the direction of the baseline and at some distance from the axis of rotation of the objective reflecting systems, a compensating reflecting system disposed behind the said intermediate system and adapted to rotate about the axial ray emerging from the said compensating system in the same sense as the said other reflecting systems, the axis of rotation of the said compensating system having the same distance from that of the said objective reflecting systems as the axial ray emerging from the said intermediate system, the said compensating system consisting of two system parts disposed one behind the other and
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- Physics & Mathematics (AREA)
- Electromagnetism (AREA)
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Description
0. BP PBNSTBIN & F. BGKARDT. TELEMETER. APPLICATION FILED APR. 24, 1913.
1,107,503. Patented Aug. 18, 191
STATES PAULWNT QFFTCE EPPEYNSTEIN AND FRIEDRICH ECKARDT, OF JENA, GERMANY, ASSIGNOBIS TU THE FIRM OF CARL ZEISS, OF JENA, GERMANY.
TELEMETER.
Specification of Letters Patent. Patented Aug. 18, 1914,
Application filed April 24, 1913. Serial No. 763,375.
To a 1071,0272- it may concern it known that we, Orro EPrnNsrnrN and FRIEDRICH Eoxano'r, citizens of the German. Empire, residing at Jena, Germany, ave invented a-new and useful Telemeter, which the following is a specification.
present invention relates to horizon- 1 tclcmcters, in which the base-line emwhen ranges are being taken, beto the instrument. In the well-known teleineters of this type, when altering the elevation, the whole instrument is rotated in about an axis parallel to the base-line, that the direction of the emerging rays direction of inspection) is altered with. the direction of the entering and by the same angle as the latter. 1 new telemeter the direction of in section is fixed and only the direction of e entering rays is variable in elevation. this purpose the two objective reflectsystems are jointly pane perpendicular to the base-line. In t or, however, to prevent the position of the images presented to the observer being influenced by the rotation of the objective rctiecting systems, a compensating reflecting m is disposed behind these systems and coupled to them in such a manner that it rotates through half as great an angle as the said systems. This may be effected by means o't' gearing or other well-known coupling means. The alteration in the posit-ion ot the images presented to the observer, which is to be obviated by the said compensating system, consists in a displacement of these images each in its plane such displacement being perpendicular to the base-line,
so tar as an intermediate reflecting systcm is jointly rotatable with the two objective reflecting systems, which permits the axial rays to emerge in a direction perpendicular to the base-line. When only the two objective reflecting systems are jointly rotatable, or when the intermediate reflecting system, while it. participates in the rotation, permits the. axial rays to emerge in he direction oi the base-line, the alteration the position or the images presented to observer, which is to be obviated, conin a IT tation of these images each in plane. Where the compensating system to obviate such a rotation of the images coincidence telcmcter, i. e. where the in t rotatable in the intermediate reflecting system is a separat- 'ing prism system, the compensating system .must be disposed in such a place that besides the said rotation of the single images a rotation of the line of coincidence in the plane of the images is also obviated; there fore, when the separating prism system is jointly rotatable with the objective reflecting systems, the compensating system must lie behind it, otherwise in front of it. The
compensating system of a stereoscopic telem- 5 eter must consist of two part-systems, through each of which passes one of the two systems of ray-pencils coming from the objectives; the same holds good for the.
compensating system of a coincidence telem eter, when the said system lies in front of the separating prism system. The possibility of losing the adjustment of the instrument, when the objective reflecting systems are rotated, is lessened, by letting the intermediate reflecting system take part in the joint rotation of the two objective reflecting systems. The construction of the lnstru- 'ment is simplified, when the compensating system is disposed behind the intermediate reflecting system; in thiscase it must be rotatable about an axis parallel to the baseline and in the same sense as the objective reflecting systems. If the intermediate reflecting system be then formed in such a manner that it will permit the axial ray to emerge in the direction of the base-line and at some distance from the axis of rotation of the objective reflecting systems, gearing. or similar means of coupling for causing the rotation of the compensating system through half the angle of rotation of the objective reflecting systems can be dispensed with, if the axis'of rotation of the compensating system be caused to coincide with the axial ray emerging from this system and be given the same distance from the axis of rotation of the objective reflecting systems as is given to the axial ray emerging from the intermediate reflecting system. For when in such a case the compensating system consists of two system-- parts disposed one behind the other, which each deflect the axial ray by 90 in one and the same plane and the front one of which is guided in the direction of the axial ray passing from it to the rear system-part, and when the front systempart is connected with the intermediate refleeting system so as to be rotatable about the axial ray emerging from the latter, the compensating system rotates during a rotation of the objective reflecting systems in the same sense as the latter and through half as great an angle.
In the annexed drawing: Figures 1 to 3 show the optical system of a stereoscopic telemeter according to the present invention. Fig. 1, in which the eye-lenses of the oculars are not shown, being a plan view with the objective reflecting systems so disposed as to permit the rays to enter the instrument in a horizontal direction, Fig. 2 a corresponding section on line 2-2 of Fig. l and Fig. 3 a similar section, belonging, however, to such a position of the objective reflecting systems that the rays entering the instrument are inclined downward. Figs. a to 7 are views of a constructional example of the telemeter according to the present invention, showing a coincidence telemeter, in the image-field of which the single image lying below the line of coincidence is inverted. In this example, Fig. 4 is an elevation partly in section along line Jr-*4: of Fig. 5, Fig. 5 a plan view, also partly in section, along line 55 of Fig. 4:, and Figs. 6 and 7 crosssections on line 66 of Fig. 5. Fig. 6 corresponds to the position of the movable parts as shown in Figs. 4 and 5, where the rays enter the instrument in the horizontal direction, and Fig. 7 shows the same parts disposed for a vertical entrance of the rays.
In the first example, Fig. 1, behind the two optical squares a a which in this case form the objective reflecting systems, the objective lenses 6 are disposed. Two reflectors 0 form an intermediate reflecting system, which allows the axial rays to emerge in a direction perpendicular to the base-line. Each ocular is formed as an angled ocular with the aid of a mirror cl lying between the field-lens e and the eye-lens c and having its reflecting surface parallel to the base line and contains in the front focal plane a measuring mark system 6. All parts lying in front of the reflectors d are assumed to be rotatable jointly with the objective reflecting systems, while the two reflectors 0? forming in this case the compensating system are to be jointly rotatable and the eye-lenses 6 which allow the rays to emerge in an inclined direction, are to be rigidly connected with the carrier of the telemcter. A straight line A A lying in the common reflecting plane of the reflectors d is assumed as the axis of rotation of the parts, which are jointly rotatable with the objective reflecting systems. The reflectors (Z are to be also rotatable about the same axis, provision being made, e. g. by suitably disposed gearing, for these reflectors to rotate in the same sense and through half as great an angle as the objective reflecting systems. In consequence of this arrangement the axial rays behind the reflectors (Z coincide, in every position of the objective reflecting systems, with the axes of the eye-lenses, so that a displacement in their planes of the images presented'to the observer will be obviated.
In the second example the two pentagonal prisms a, which form the objective reflecting systems, and the objective lenses 6 lying behind them are rigidly fixed to a tube f which is journaled in a casing f in such a manner that it can be rotated about its axis by means of a handle f". A pivot f on this casing serves for inserting the instrument in a tripod head. A glass wedge 9 gearing g for displacing the said wedge in the axial direction of the tube f and a scale g behind a window g indicate the measuring device. The separating prism system it, 72?, h in which the upper half of the cement layer between it and k is replaced by a separating layer it", which is reflecting on both sides, lets the axial ray emerge in the direction of the base-line and is also rigidly fixed to the tube f so as to be rotatable jointly with the objective reflecting systems. The mixed ray-pencil system emerging from the separating prism system in the direction of the base-line is received by a collective lens t and is transmitted by means of a reversing lens system, between the two members 2' and i of which the rays forming a pencil are parallel to one another, and three simple reflecting prisms k, k and la each of which deflects by 90, to the ocular system 6 6 from which the axial ray emerges in an upwardly inclined direction. The two prisms and 70 which deflect the axial ray in one and the same plane and in the same sense, form in this case the compensating system. The prismlc which forms the front system-part, can slide by means of a hole in its mounting Z on a pin on, which is fixed to the mounting Z of the prism 70 forming the rear system-part, so that the prism k is guided in the direction of the axial ray pass- I ing from it to the prism 70 The prism mounting Z is journaled in a bearing 12 fixed to the casing f the axis of which bearing coincides with the axial ray emerging from the prism It, so that the compensating system is rotatable about the axial ray emerging from it. Its axis of rotation and the axial ray emerging from the separating prism system are equidistant from the axis of the tube P. For coupling the compensating system with the objective reflecting systems there is fixed to the tube f a hearing m in which the prism mounting Z is rotatable, and the axis of which coincides with the axial ray emerging from the separating prism system. On the tube f being rotated the prism 7&1 slides on its guide and the compensating system rotates through an ed to maintain a fixed direction during such rotation, two objective systems disposed behind the said objective reflecting systems, an intermediate reflecting system and a compensating reflecting system, these two latter systems being also disposed behind the said objective reflecting systems, a measuring device and means for coupling the said ob jective reflecting systems and the said compensating system, these means being adapted to transmit half the rotation of the objective reflecting systems to the compensat ing system.
Horizontal telemeter comprising an ocular system, two objective reflecting systems, means for rotating the said objective reflecting systems jointly about an axis parallel to the base-line, the axis of emergence of the said ocular system being adapted to maintain a fixed direction during such rotation, two objective systems disposed behind the said objective reflecting systems, an intermediate reflecting system disposed behind the said objective reflecting systems and adapted to rot-ate about an axis parallel to the base-line through the same angle and in the same sense as the latter systems,
a compensating reflecting system dispoflcil behind the said intermediate system and adapted to rotate about an axis parallel to the base-line and in the same sense as the said other reflecting systems, a measuring device and means for coupling the said objective reflecting systems and the said com;
pensating svstem, these means being adapted to transmit half the rotation of the objective reflecting systems to the compensating system.
3. Horizontal telemeter comprising an ocular system, two objective reflecting systems, means for rotating the said objective reflecting systems jointly about an axis parallel to the base-line, the axis of emergence of the said ocular system being adapted to maintain a fixed direction during such rotation, a measuring device, two objective systems disposed behind the said objective reflecting systems, an intermediate reflecting system disposed behind the said objective reflecting systems and adapted to rotate about an axis parallel to the base-line through the same angle and in the same sense as the latter systems and to let the axial ray emerge in the direction of the baseline and at some distance from the axis of rotation of the objective reflecting systems, a compensating reflecting system disposed behind the said intermediate system and adapted to rotate about the axial ray emerging from the said compensating system in the same sense as the said other reflecting systems, the axis of rotation of the said compensating system having the same distance from that of the said objective reflecting systems as the axial ray emerging from the said intermediate system, the said compensating system consisting of two system parts disposed one behind the other and adapted each to deflect the axial ray through 90 in one and the same plane, a guiding member, on which the front system-part is guided in the direction of the axial ray passing from it to the rear systempart, connecting means between the said frontsystem-part and the said intermediat'e's ystem, adapted to render the former rotatable about the axial ray emerging from the latter.
OTTO EIPENS' lllN. FRIEDRICH ECKARDT.
\Vitnesses ..v....li-\UL Klu'ionn, Fnrrz LANDER.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US76337513A US1107503A (en) | 1913-04-24 | 1913-04-24 | Telemeter. |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US76337513A US1107503A (en) | 1913-04-24 | 1913-04-24 | Telemeter. |
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US1107503A true US1107503A (en) | 1914-08-18 |
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US76337513A Expired - Lifetime US1107503A (en) | 1913-04-24 | 1913-04-24 | Telemeter. |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2422710A (en) * | 1944-05-10 | 1947-06-24 | Zaroodny Serge John | Stereoscopic gun sight having fixed oculars and objectives movable with the gun |
US2625853A (en) * | 1948-02-03 | 1953-01-20 | Hayward Roger | Panoramic telescope device |
US2625854A (en) * | 1947-12-02 | 1953-01-20 | Hayward Roger | Panoramic binocular telescope |
-
1913
- 1913-04-24 US US76337513A patent/US1107503A/en not_active Expired - Lifetime
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2422710A (en) * | 1944-05-10 | 1947-06-24 | Zaroodny Serge John | Stereoscopic gun sight having fixed oculars and objectives movable with the gun |
US2625854A (en) * | 1947-12-02 | 1953-01-20 | Hayward Roger | Panoramic binocular telescope |
US2625853A (en) * | 1948-02-03 | 1953-01-20 | Hayward Roger | Panoramic telescope device |
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