US1945096A - Convertible band pass receiver - Google Patents
Convertible band pass receiver Download PDFInfo
- Publication number
- US1945096A US1945096A US516549A US51654931A US1945096A US 1945096 A US1945096 A US 1945096A US 516549 A US516549 A US 516549A US 51654931 A US51654931 A US 51654931A US 1945096 A US1945096 A US 1945096A
- Authority
- US
- United States
- Prior art keywords
- circuits
- tuning
- condenser
- condensers
- circuit
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
Images
Classifications
-
- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03J—TUNING RESONANT CIRCUITS; SELECTING RESONANT CIRCUITS
- H03J3/00—Continuous tuning
- H03J3/02—Details
- H03J3/06—Arrangements for obtaining constant bandwidth or gain throughout tuning range or ranges
- H03J3/08—Arrangements for obtaining constant bandwidth or gain throughout tuning range or ranges by varying a second parameter simultaneously with the tuning, e.g. coupling bandpass filter
Definitions
- My present invention relates to a radio receiving set comprising a plurality of tuned circuits, the condensers of which are mounted on one shaft.
- the selectivity of the system may increase too much so that on receipt of telephony the high tones coming through are too weak in relation to the low tones.
- each of the various circuits, or all the circuits but one include, in series with the variable condenser, a preferably fixed condenser so that the various circuits become somewhat mistuned with relation to each other. This results in the resonance curve being more enlarged at the end of the long wave than at the end of the short wave.
- the tuning of the first tuned circuit is preferably chosen between those of the other circuits so that there are circuits with a tuning higher than that of the said circuit, equally well as circuits with a tuning lower than that of the said circuit. That is, the resonance curves of the circuits are staggered. This choice is desirable, as obviously it is important that the middle point of the resonance curve should coincide with the carrier wave of the signals to be received, with the usual symmetrical modulation of the carrier wave.
- the first circuit were to be tuned slightly beside the carrier wave a powerful signal having a wave length little different from that of the signals to be received would easily modulate the carrier wave to be received so that disturbing oscillations would be introduced which could no longer be suppressed by the means of selection following the first circuit as they have partly the same frequency as those composing the signal to be received.
- switches may be used by means of which the fixed condensers for the short wave-zone are shortcircuited. This may be effected, for example, by the switch by means of which the change in connections to the various zones of wave lengths is performed.
- 1, 2 and 3 designate three tuned circuits the tuning condensers l, 5 and 6 of which are mounted on one shaft 6'.
- '7 and 8 are fixed condensers.
- the fixed condensers have a capacity which is several times greater than the maximum capacity of the tuning condensers. In one practical embodiment the capacity of condenser 7 was 15,000 czn., and that of condenser 8 was 16,308 cm.
- the circuit 1, which includes the largest condenser is chosen as the first circuit.
- the resonance curves of the different circuits are shown as staggered in Fig. 2, and referred to by the same numerals as the tuned circuits.
- the combined resonance curve is designated by 11. As the damping of the circuits 1 and 2 is but slight, the combined resonance curve is rather steep on either side.
- Fig. 1 designates a switch by means of which part of the self-induction oi the circuits can be short-circuited so as to effect the passing to another zone of waves.
- the fixed condenser is also short-circuited by the switch.
- the damping of the grid circuit oi the detector tube is sligl'itly'greater than that of the other circuits.
- the resonance curve of the circuit 3 is slightly more enlarged, and slightly lower than that of the other circuits which may give rise to a slight asymmetry in the resulting resonance curve. This asymmetry is, however, of little importance. If desired, it may be compensated for by initially imparting to the tuned circuit to be coupled to the detector, a slightly lower damping than the other circuits.
- a series of tunable circuits coupling each pair or" adjacent circuits, reactive means in at least two or" said circuits to efiect such staggering of the resonance curves of all the circuits that the over-all resonance curve of the circuits is Wider when receiving long waves than when receiving short waves, and means for selectively rendering said last means inoperative for receiving short waves.
- each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being different and so chosen that the circuits are sufficiently staggered in tuning to produce an over-all resonance curve of the circuits which is wider at the long Wave end of the receiver tuning range than at the short Wave end.
- each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the tuning of the circuits at any setting of the means is staggered and the overall resonance curve of the circuits is wider at the long wave end of the receiver tuning range than at the short wave end, the fixed condenser in the first circuit being larger.
- each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser oi the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the circuits are resonant to diiierent frequencies at any setting of the adjusting means and the first of said circuits is resonant to a frequency inter mediate the frequencies of the other two circuits.
- each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the said circuits are resonant to different frequencies and the over-all resonance curve of the circuits is wider at the long wave end of the r DCver tuning range than at the short wave end, and means for short-circuiting said fixed condensers at the said short Wave end.
- each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the over-all resonance curve of the circuits is wider at the long Wave end of the receiver tuning range than at the short Wave end, said fixed condensers having a capacity relatively greater than the maximum capacity of the tuning condensers.
- each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the over-all resonance curve of the circuits is wider at the long Wave end of the receiver tuning range than at the short wave end and the fixed condenser in the first circuit being larger than the xed condenser in the third circuit.
- each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the, first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the over-all resonance curve of the circuits is wider at the long Wave end of the receiver tuning range than at the short wave end, a load coupled to the last circuit which excessively damps the latter, the damping of the third circuit being slightly lower than the damping of the preceding circuits to compensate for said excessive damping.
- each circuit including an inductance coil and a variable tuning condenser, a fixed condenser connected with the coil and tuning condenser of at least the first and last of said circuits, for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being difierent and so chosen that the first circuit is resonant, at any setting of said adjusting means, to a desired carrier while the other two circuits are resonant to frequencies above and below said carrier.
- each circuit including an inductance coil and a variable tuning condenser, a fixed condenser connected with the coil and tuning condenser of at least the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being different and so chosen that the first circuit is resonant, at any setting of said adjusting means, to a desired carrier while the other two circuits are resonant to frequencies above and below said carrier, the over-all resonance curve of said circuits being wider at the long wave end of the receiver tuning range than at the short wave end.
Landscapes
- Magnetic Resonance Imaging Apparatus (AREA)
Description
30, 1934- B. D. H. TELLEGEN ,945,096
CONVERTIBLE BAND PASS RECEIVER Filed Feb. 18. 1931 1;" HP if i 373 INVENTOR BERNARDUS D.H.TELLEGEN ATTORNEY Patented Jan. 30, 1934 Bernardus Borninicus Hnhertus Tellegen, Eindhoven, Netherlands, assignor to Radio Corporation of America, a corporation of Delaware Application February 18, 1931, Serial No. 516,549,
and in 10 Claims.
My present invention relates to a radio receiving set comprising a plurality of tuned circuits, the condensers of which are mounted on one shaft.
When using circuits of comparatively low damping, and particularly when the circuits are equalized as far as possible, the selectivity of the system may increase too much so that on receipt of telephony the high tones coming through are too weak in relation to the low tones.
According to the present invention, in order that the advantage of circuits of low damping may be conserved, each of the various circuits, or all the circuits but one, include, in series with the variable condenser, a preferably fixed condenser so that the various circuits become somewhat mistuned with relation to each other. This results in the resonance curve being more enlarged at the end of the long wave than at the end of the short wave.
According to the invention, the tuning of the first tuned circuit is preferably chosen between those of the other circuits so that there are circuits with a tuning higher than that of the said circuit, equally well as circuits with a tuning lower than that of the said circuit. That is, the resonance curves of the circuits are staggered. This choice is desirable, as obviously it is important that the middle point of the resonance curve should coincide with the carrier wave of the signals to be received, with the usual symmetrical modulation of the carrier wave.
If the first circuit were to be tuned slightly beside the carrier wave a powerful signal having a wave length little different from that of the signals to be received would easily modulate the carrier wave to be received so that disturbing oscillations would be introduced which could no longer be suppressed by the means of selection following the first circuit as they have partly the same frequency as those composing the signal to be received.
It has been found that generally the measures hereinbefore described are unnecessary for receiving short waves since in this zone of wavelengths the damping of the various circuits is inherently sufiiciently great. For this reason switches may be used by means of which the fixed condensers for the short wave-zone are shortcircuited. This may be effected, for example, by the switch by means of which the change in connections to the various zones of wave lengths is performed.
The novel features which I believe to be characteristic of my invention are set forth in parthe Netherlands April 15, 1930 ticularity in the appended claims, the invention itself, however, as to both its organization and method of operation will best be understood by reference to the following description taken in connection with the drawing in which I have in- 0 dicated diagrammatically one circuit organization whereby my invention may be carried into effect.
In order that the invention may be clearly understood and readily carried into effect, one form of construction of the circuit arrangement according to the invention will be described more fully with reference to the accompanying drawing in which this circuit arrangement is diagrammatically illustrated.
Referring to 1, 1, 2 and 3 designate three tuned circuits the tuning condensers l, 5 and 6 of which are mounted on one shaft 6'. '7 and 8 are fixed condensers. The fixed condensers have a capacity which is several times greater than the maximum capacity of the tuning condensers. In one practical embodiment the capacity of condenser 7 was 15,000 czn., and that of condenser 8 was 16,308 cm. Preferably, the circuit 1, which includes the largest condenser, is chosen as the first circuit.
The resonance curves of the different circuits are shown as staggered in Fig. 2, and referred to by the same numerals as the tuned circuits. The combined resonance curve is designated by 11. As the damping of the circuits 1 and 2 is but slight, the combined resonance curve is rather steep on either side.
In Fig. 1, 10 designates a switch by means of which part of the self-induction oi the circuits can be short-circuited so as to effect the passing to another zone of waves. In the circuits 1 and 3 the fixed condenser is also short-circuited by the switch.
Frequently, the damping of the grid circuit oi the detector tube is sligl'itly'greater than that of the other circuits. In this case the resonance curve of the circuit 3 is slightly more enlarged, and slightly lower than that of the other circuits which may give rise to a slight asymmetry in the resulting resonance curve. This asymmetry is, however, of little importance. If desired, it may be compensated for by initially imparting to the tuned circuit to be coupled to the detector, a slightly lower damping than the other circuits.
By a suitably chosen measure of artificial damping reduction (retroaction) provision may be made for the resonance keenness of this circuit being equalized with that of the other circuits. Further, while I have indicated and described one arrangement for carrying my invention into effect, it will be apparent to one skilled in the art that my invention is by no means limited to the particular organization shown and described, but that many modifications may be made without departing from the scope of my invention as set forth in the appended claims.
What I claim is:
1. In combination, a series of tunable circuits, a space discharge device coupling each pair or" adjacent circuits, reactive means in at least two or" said circuits to efiect such staggering of the resonance curves of all the circuits that the over-all resonance curve of the circuits is Wider when receiving long waves than when receiving short waves, and means for selectively rendering said last means inoperative for receiving short waves.
2. In a radio receiver, at least three cascaded oscillation circuits, an electron discharge tube coupling each pair of successive circuits, each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being different and so chosen that the circuits are sufficiently staggered in tuning to produce an over-all resonance curve of the circuits which is wider at the long Wave end of the receiver tuning range than at the short Wave end.
3. In a radio receiver, at least three cascade oscillation circuits of relatively low damping, each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the tuning of the circuits at any setting of the means is staggered and the overall resonance curve of the circuits is wider at the long wave end of the receiver tuning range than at the short wave end, the fixed condenser in the first circuit being larger.
4-.. In a radio receiver, at least three cascaded oscillation circuits, an electron discharge tube coupling each pair of successive circuits, each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser oi the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the circuits are resonant to diiierent frequencies at any setting of the adjusting means and the first of said circuits is resonant to a frequency inter mediate the frequencies of the other two circuits.
5. In a radio receiver, at least three cascaded oscillation circuits, each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the said circuits are resonant to different frequencies and the over-all resonance curve of the circuits is wider at the long wave end of the r ceiver tuning range than at the short wave end, and means for short-circuiting said fixed condensers at the said short Wave end.
6. In a radio receiver, at least three cascaded oscillation circuits, an electron discharge tube coupling each pair of successive circuits, each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the over-all resonance curve of the circuits is wider at the long Wave end of the receiver tuning range than at the short Wave end, said fixed condensers having a capacity relatively greater than the maximum capacity of the tuning condensers.
7. In a radio receiver, at least three cascaded oscilation circuits, an electron discharge tube coupling each pair of successive circuits, each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the over-all resonance curve of the circuits is wider at the long Wave end of the receiver tuning range than at the short wave end and the fixed condenser in the first circuit being larger than the xed condenser in the third circuit.
8. In a radio receiver, at least three cascaded oscillation circuits, each circuit including an inductance coil and a variable tuning condenser, a fixed condenser in series with the coil and tuning condenser of the, first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being so chosen that the over-all resonance curve of the circuits is wider at the long Wave end of the receiver tuning range than at the short wave end, a load coupled to the last circuit which excessively damps the latter, the damping of the third circuit being slightly lower than the damping of the preceding circuits to compensate for said excessive damping.
9. In a radio receiver, at least three cascaded oscillation circuits, each circuit including an inductance coil and a variable tuning condenser, a fixed condenser connected with the coil and tuning condenser of at least the first and last of said circuits, for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being difierent and so chosen that the first circuit is resonant, at any setting of said adjusting means, to a desired carrier while the other two circuits are resonant to frequencies above and below said carrier.
10. In a radio receiver, at least three cascaded oscillation circuits, each circuit including an inductance coil and a variable tuning condenser, a fixed condenser connected with the coil and tuning condenser of at least the first and last of said circuits, means for simultaneously adjusting said tuning condensers, the magnitudes of said fixed condensers being different and so chosen that the first circuit is resonant, at any setting of said adjusting means, to a desired carrier while the other two circuits are resonant to frequencies above and below said carrier, the over-all resonance curve of said circuits being wider at the long wave end of the receiver tuning range than at the short wave end.
BERNARDUS DOMINICUS HUBERTUS TELLEGEN.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
NL1945096X | 1930-04-15 |
Publications (1)
Publication Number | Publication Date |
---|---|
US1945096A true US1945096A (en) | 1934-01-30 |
Family
ID=19873348
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US516549A Expired - Lifetime US1945096A (en) | 1930-04-15 | 1931-02-18 | Convertible band pass receiver |
Country Status (1)
Country | Link |
---|---|
US (1) | US1945096A (en) |
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2540532A (en) * | 1945-12-18 | 1951-02-06 | Rca Corp | Superheterodyne receiver with compensation for mistuning caused by automatic volume control |
US2579345A (en) * | 1947-07-05 | 1951-12-18 | Rca Corp | Amplifier band width control |
US2706290A (en) * | 1943-09-20 | 1955-04-12 | Fox Benjamin | Monitoring system |
US2710315A (en) * | 1950-11-03 | 1955-06-07 | Ben H Tongue | Wide-band amplifying system |
US2710314A (en) * | 1950-06-08 | 1955-06-07 | Tongue Ben Hapgood | Wide-band amplifying system |
US2989581A (en) * | 1954-04-23 | 1961-06-20 | Rca Corp | Color television receiver signal transfer system |
US3009108A (en) * | 1951-07-06 | 1961-11-14 | Lufttechnischen Ges M B H | Measurement of electric charges put on a condenser |
-
1931
- 1931-02-18 US US516549A patent/US1945096A/en not_active Expired - Lifetime
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2706290A (en) * | 1943-09-20 | 1955-04-12 | Fox Benjamin | Monitoring system |
US2540532A (en) * | 1945-12-18 | 1951-02-06 | Rca Corp | Superheterodyne receiver with compensation for mistuning caused by automatic volume control |
US2579345A (en) * | 1947-07-05 | 1951-12-18 | Rca Corp | Amplifier band width control |
US2710314A (en) * | 1950-06-08 | 1955-06-07 | Tongue Ben Hapgood | Wide-band amplifying system |
US2710315A (en) * | 1950-11-03 | 1955-06-07 | Ben H Tongue | Wide-band amplifying system |
US3009108A (en) * | 1951-07-06 | 1961-11-14 | Lufttechnischen Ges M B H | Measurement of electric charges put on a condenser |
US2989581A (en) * | 1954-04-23 | 1961-06-20 | Rca Corp | Color television receiver signal transfer system |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US2141756A (en) | Multirange receiver | |
US1945096A (en) | Convertible band pass receiver | |
US2434299A (en) | Radio receiver with band-spread control for a number of comparatively narrow frequency bands | |
US2174963A (en) | Electrical wave resonant line filter | |
US2540532A (en) | Superheterodyne receiver with compensation for mistuning caused by automatic volume control | |
US1947229A (en) | Heterodyne receiving system | |
US2093416A (en) | Feedback circuits | |
US1933778A (en) | Radio receiving system | |
US2129026A (en) | Tuning range adjustment device | |
US2219396A (en) | Electric translating system | |
US2468041A (en) | Radio receiver | |
US2226488A (en) | Radio frequency rejector circuit | |
US1987984A (en) | Adjacent channel selectivity | |
US2091134A (en) | Amplifier | |
US2017131A (en) | Intermediate frequency amplifier | |
US2161646A (en) | Band-pass filter with variable band width | |
US2182328A (en) | Band width and tone control circuit | |
US2034773A (en) | Tunable radio frequency circuits | |
US2259596A (en) | Band receiving system | |
US2517741A (en) | Permeability-tuned variable-frequency amplifier | |
US2133808A (en) | Radio receiver | |
US2259595A (en) | Band receiving system | |
US2020377A (en) | Band pass circuit | |
US2156137A (en) | Band-pass selector | |
US1921088A (en) | Wave signaling system |