NO742500L - - Google Patents

Description

Damping device for radio transmitters.

This invention relates to improvements in preselection arrangements for radio transmitters and is described in connection with a marine radiotelephone transmitter, but is not limited to this application.

The invention provides a preselection radio transmitter in which any desired setting of a tuning capacitor and any desired tuning state of a tuning inductor can be assigned to each of a plurality of preselected tuning channels.

According to this invention, there is provided a tuning device which is tunable to any of a plurality of predetermined frequencies selected by the setting of a multi-position selector switch, wherein a first section of the switch is adapted to regulate the value of an inductance which is adapted to be connected in series between the power amplifier stage in a transmitter and an antenna*and another section of the inverter is arranged to regulate the value of a capacitance arranged so that it can be connected in parallel with the output of the power amplifier stage, and where each of the contacts in the said first and second section of the inverter is arranged to be connectable to effect activation of a first or a second actuator device, respectively, which sets the respective values, in any one of a plurality of predetermined positions.

The invention shall further be described by application for tuning the antenna circuit in a transmitter, but it will be realized that it can just as well be used for tuning other transmitter stages if desired.

An embodiment of the invention will be described in the following with reference to the drawings, of which

Figure 1 is a schematic block diagram of a radio transmitter using the present invention and

Figure 2 is a schematic of channel preselection polling arrangements according to this invention.

The radio transmitter in Figure 1 comprises a microphone 1 which emits speech signals to a low-frequency amplifier 2. The amplified low-frequency signals from the amplifier 2 are delivered to a radio modulator 3 where they are used to modulate a radio frequency signal from an oscillator not shown, whereby a modulated radio frequency signal which is fed to a mixer 4 in which the modulated radio frequency signal is combined with that signal from a kxys-tallo oscillator 5 to obtain a signal at the frequency at which the transmission is desired. The crystal 6 used for each selected channel is determined by a deck 7a in a channel selector 7, in which two further decks 7b, 7c are used to regulate the tuning of the antenna circuit as will be described later. The modulated signal at the transmitter frequency, which is produced by the mixer 4, is applied to an amplifier 8 and then delivered to an antenna circuit comprising a variable capacitor 9 connected in parallel, and an adjustable induction coil 10 connected in series, which coil is shown as on induction coil with several outlets, as other forms of adjustment or regulation can also be used if that is preferable. The capacitor 9 and the induction coil 10 are set to values that correspond to the frequency to be probed, under control of the decks 7b and 7c in the selector 7, each of these decks having its contacts connected to an associated programmable control device 11 and 12 which is arranged to be able to set respectively the capacitor 9 and the induction coil 10 in any of a plurality of states depending on the energization of each control input from a tire 1 the inverter 7.

Figure 2 shows an advantageous embodiment of the programmable control devices or oscillators 11 and 12. Each of the decks 7b and 7c in the channel selector 7 comprises a movable contact part by means of which the negative pole of a direct current supply can be connected to any of 23 fixed contacts. The operation of the control system 11 for tuning the capacitor 9 will first be described. Each of the fixed © contacts in the selector deck 7b is, by means of a separate connecting wire, of which only three are shown, connected to an associated conductor of 23 conductors 13a arranged in a first parallel group on a tuning capacitor selector plate 13. Each of the conductors 13a can be connected to any one of 35 conductors 13b in another parallel group arranged perpendicularly to the conductors in the first group, means for interconnection between the conductors at each crossing point being provided. Each of the 35 conductors 13b in the second group is connected by means of a separate connecting line to an associated one of the fixed contacts 14a in a selector switch 14 with 35 positions. The movable contact 14b in the inverter 14 is connected to the control-base electrode in a Darlington transistor pair which regulates the supply of direct current from a suitable current source to a stepping motor 17. The motor is connected through a reduction ion drive 18 so that it drives both the inverter 14 and the tuning capacitor 9. Due to the inverting effect of the Darlington transistor pair, the motor 17 will be fed with current until the movable contact 14b in the inverter 14 comes to the fixed contact 14a which, with the help of the selection plate 13 and the selection inverter 7, is held at the negative potential of the power supply. When this happens, the transistor pair will be blocked and the motor will stop. It will be seen that in this way any of 35 different settings of the tuning capacitor 9 can be selected for each channel section position of the inverter 7.

In a preferred embodiment of the device described above, the tuning capacitor 9, whose maximum capacity is 1000 pF, has semi-circular movable plates and is not provided with stopping means, so that it is allowed to rotate continuously in one and the same direction. The shaft of the capacitor is provided with a cam 19 which extends over 180° and which affects a switch 20 by means of which a fixed capacitor 21 with a value of 970 pF is connected in parallel with the tuning capacitor 9 during a sweep of the movable plates between the smallest and the largest capacity of the capacitor 9. This arrangement enables selection of 35 capacitor values in the range from 0 to 1,970 pF.

The programmable control device 12 for selecting the outlet on the Induction Coil is based on a principle very similar to that described above in connection with the tuning capacitor. Each of the 23 contacts in a channel selector reverse deck 7b is connected through an individual connection line to a corresponding first group of conductors 23a on a socket selector plate 23 which has another group consisting of 12 conductors 23b and is individually connected to an associated fixed contact in a first tire 24a in a switch 24 with 12 positions. This tire is a "homing" tire in which the movable contact 24c makes contact with all but one of the fixed contacts in the tire. The movable contact is connected to a stepper motor 25 which is connected to drive the inverter and is connected to the positive pole of the direct current source. In this way, the stepping motor 25 will drive the inverter 25 until the excluded contact is the one connected to the negative pole of the power source by means of the outlet weighing plate 23 and the channel selector inverter 7c. Another tire 24b in the turner 24 has its movable contact 24d connected to one end of the tuning coil 10, together with one of its 12 fixed contacts. The remaining 11 fixed contacts are connected to respective outlet points on the induction coil 11 so that 12 different inductive!theta values can be selected for each channel setting of the inverter 7.

Claims (8)

1. Tuning device for radio transmitters tunable to any of a plurality of predetermined frequencies selected by the setting of a multi-position selector switch, characterized in that a first section of the switch is adapted to regulate the value of an induction coil adapted to be connected in series between the power amplifier stage in a transmitter and an antenna, and another section of the inverter is arranged to regulate the value of a capacity arranged to be connected in parallel with the output of the power amplifier stage, and that each of the contacts in the first and second inverter sections respectively is arranged to be able to be connected to effect activation of respectively a first or a second actuator device which regulates the relevant said value to any one of a plurality of predetermined positions. 2. Device according to claim 1, characterized in that the actuator device has a plurality of control lines whose energization causes the actuator device to take a separate position and that each contact in the first turning section is arranged to be able to be connected to any of the control lines in the first actuator device and each contact in the other turns section is arranged to be able to be connected to any of the other leads in the other actuator device. 3. Device according to claim 2, characterized in that each of the contacts in the first facing section is connected to an associated conductor in a first group of parallel conductors which are placed across another group of parallel conductors which are each connected to an associated control line in the first actuator device, with on device by means of which each of the conductors in the first group can be connected to any of the conductors in the second group and that each of the contacts in the second faces section is connected to an associated conductor in the third group of conductors which lies across a fourth group of parallel conductors each of which is connected to an associated control wire in don second actuator device, as well as a device by means of which each of the conductors in don third group can be associated with any of the leaders in the fourth group. 4. Device according to claim 1, 2 or 3, characterized in that the first actuator device comprises a drive motor, designed to adjust the value of the capacity and also to influence a switch with several positions and whose movable contact is led to a control terminal on an energizing circuit for the motor, and the fixed contacts are arranged to selectively connect to a voltage source in accordance with the setting of the selector switch, so that the motor is energized until the movable contact contacts the fixed contact connected to the voltage source , whereby the capacity is set to a value corresponding to the setting of the selector switch. 5. Device according to claim 4, characterized in that the capacity comprises a variable capacitor with a continuously rotatable rotor and whose rotor shaft arms a cam that affects a switch by means of which a fixed capacitor is connected in parallel with the variable capacitor during rotation of the shaft through an angular range of 180°. 6. Device according to claim 4 or 5, characterized in that the movable contact 1 multi-position inverter is connected to the basis of the controlling transistor 1, a Darlington transformer pair designed to supply electric current to the drive motor, and the fixed contacts each through a contact in the select inverter is connected to a voltage source so that said transistor is blocked when the voltage is applied to said base. 7. Device according to one of claims 1 to 6, characterized in that the second actuator device comprises a further drive motor arranged to influence a £ler position inverter arranged to vary the effective inductance of an induction coil and to influence a "homing" inverter with a movable contact provided with a gap and arranged to control the further drive motor, where the fixed contactors of the "homing" inverter are arranged to be selectively connected to a voltage source 1 in accordance with the setting of the selector inverter so that the motor is energized until the gap in the moving contact comes to the fixed contact selected by the selector switch. 8. Device according to claim 3 or one of claims 4 - 7 and claim 3, characterized in that the parallel groups of conductors are formed on opposite sides of a double-sided printed circuit board.