DE4420876C2 - Circuit arrangement for recording signals - Google Patents

Description

The invention relates to a circuit arrangement for Record signals on a magnetic medium.

With magnetic recording / playback devices with a rotating scanner in one Recording operation electrical signals from one fixed part to a rotating part of the Transfer scanner. The rotating part of the Scanning device, e.g. B. a rotating top drum or a rotating top wheel, carries at least around its circumference a magnetic head over a rotating transformer the signals for magnetic recording on one magnetic carriers are supplied. For magnetic Recording of very broadband signals is added in the signal path between the rotor winding of the rotating Transformer and the magnetic head one Voice amplifier one of the required Recording current for the magnetic head and delivers generated recording current on a short way in the Feeds the head winding of the magnetic head.

Such a speech amplifier arrangement is known from DE 42 16 668 A1 known. In this known arrangement two end transistors feed push-pull currents in the middle tapped head winding of a Magnetic head. In each emitter line of the two  End transistors, an emitter resistor is arranged, the depending on the collector current of the final transistor Voltage drop. The falling voltage will via a resistor to the input from each End transistors assigned to preamplifiers. This known voice amplifier arrangement has the Disadvantage that due to circuit asymmetries different direct currents in the two End transistors can flow. This effect is called DC offset called. The DC offset causes non-linear signal distortion. Besides, can it to a larger DC offset unwanted erasure of the magnetic tape.

Furthermore, from US 4,473,804 a linear class B Transconductance power amplifier for power supply a center tapped convergence coil in one Color television receiver known. Here is in the emitter Leads of two end transistors, their Collector connections with winding ends of the convergence coil connected, a resistor is inserted. The on the voltages dropping are above each a resistance to the base connections of two Pre-transistors of an inverted conductivity type fed back as a differential amplifier are switched. The collector connections of the Pre-transistors are connected to the base terminals of the End transistors connected. One of the basic connections of the Pre-transistors is a resistor Input signal applied; the other basic connection the Pre-transistors are at a fixed potential. On such amplifier is due to class B operation unsuitable for recording signals on magnetic tape.

The present invention is based on the object  a circuit arrangement for the magnetic recording of signals the offset Improve the behavior of the two end transistors.

This object is achieved by two current sources which can be controlled by the signals to be recorded, for delivering response currents to the center-tapped winding of an impact magnetic head, two resistors assigned to the current sources, via which the response currents emitted by the current sources flow, and a device for amplifying the difference from the resistances falling voltages with a reference voltage at which the outputs of the device are connected to control inputs of the two current sources ( 6 , 7 ).

According to a development of the invention, those falling on the resistors are Tensions subject to integration.

The circuit arrangement according to the invention has the advantage that an offset Compensation the DC components emitted by the current sources are now the same being held. Non-linear distortion in the playback signal or unwanted Erasing the magnetic tape due to asymmetries of the speech amplifier circuit can be excluded.

In a specific circuit arrangement, a first and a second transistor are provided, which emitter connections have a first and a second resistor on a first fixed potential at which base connections the signal to be recorded is fed and at which collector connections each with a middle at the winding ends tap provided winding of a magnetic head are connected, the  Tapping is at a second fixed potential, and a third and fourth transistor in Differential amplifier circuit, with which basic connections one each at the emitter connections of the first and second transistor detachable signal is supplied and for which collector connections each with a Base terminal of the first and second transistor connected are.

The circuit arrangement according to the invention is one Integration accessible because of the transistors used are of the same conductivity type. There is also at a discrete circuit structure is no longer necessary, to pair the transistors or only one transistors Wafers to use to circuitry symmetrize. Temperature-related voltage drifts of the Base-emitter voltages of the two end transistors act no longer as a collector current offset. Moreover is advantageous that for speaking very broadband signals only the two End transistors must have high transit frequencies.

In a further embodiment of the invention provided the emitter connections of the third and fourth To connect transistors with each other and via a to put third resistance to the first fixed potential so that depending on the resistance value of the third Resistance the size of the in the winding of the Magnetic head flowing recording current can be set can.

According to another embodiment, it is provided that between the emitter connections of the first and second Transistor and the base connections of the third and fourth transistor, a resistor is inserted  and that the emitter and base connection of both the third and fourth transistor with a capacitor are connected. The result of this resistance and that This is determined by the capacitor resulting time constant Control behavior of offset compensation.

By those listed in the further subclaims Measures are advantageous training and Improvement in the specified in claim 1 Circuit arrangement possible.

In the following an embodiment of the Circuit arrangement according to the invention with reference to the drawing explained in more detail. Show it:

Fig. 1 shows a basic circuit according to the invention and

Fig. 2 shows a concrete embodiment of the circuit arrangement according to the invention.

In the figures, the same parts have the same reference characters.

In Fig. 1, 1 denotes the stationary winding (stator winding) of a rotating transformer 2 . The stator winding 1 is connected to a signal generator 3 which has an internal resistance 4 . The signal generator 3 emits the signal to be recorded, which passes from the stator winding 1 to a rotor winding 5 by inductive coupling of the rotating transformer 2 .

The rotating transformer 2 serving as a signal transmission path is arranged within a rotating scanning device, which consists, for example, of fixed drums arranged concentrically to one another and a top wheel disk rotating concentrically therewith in a dividing joint between the two drums. Several recording, playback and erasing magnetic heads are attached to the circumference of the head wheel disc and scan a magnetic tape which is helically wound around the concentrically arranged drums.

As mentioned at the beginning, amplifiers are inserted into the signal transmission path between the individual rotor windings and their associated magnetic heads in order to reduce signal transmission loss on the one hand and on the other hand to improve the signal / interference ratio between the recording and playback channels. In Fig. 1, the signal to be recorded on the rotor winding 5 is located at control inputs of two push-pull controllable current sources 6 and 7 , the outputs of which are connected via terminals 8 and 9 to winding ends of a center-tapped head winding 10 of a magnetic head 11 .

The center tap (terminal 12 ) of the head winding 10 is connected to a positive operating voltage (terminal 13 ). In the recording current lines of the two controllable current sources 6 and 7 , a resistor 14 , 15 is inserted in each case against ground potential. The voltage dropping across the resistor 14 passes through a resistor 16 to the inverting input of an operational amplifier 17 , the output of which is connected to the control input of the controllable current source 6 . The inverting input and the output of the operational amplifier 17 are bridged by a capacitor 18 . In a corresponding manner, the voltage which can be tapped off at the resistor 15 reaches the inverting input of an operational amplifier 20 via a resistor 19 . The output of the operational amplifier 20 is connected to the control input of the controllable current source 7 . A capacitor 21 is located between the output and the inverting input of the operational amplifier 20 . The non-inverting inputs of the two operational amplifiers 17 and 20 are connected to one another; they are at the output of a reference voltage source 22 , which is connected to ground potential. A capacitor 23 is inserted into a line of the rotor winding 5 for DC voltage separation. A matching resistor 24 can be connected in parallel with the rotor winding 5 .

The basic circuit of FIG. 1 has the following mode of operation:
The induced by the stator 1 in the rotor winding 5 of the rotary transformer 2 aufzusprechende signal of the signal generator 3 controls the current sources 6 and 7, which operate in push-pull operation. At the output of the current sources 6 and 7 , alternating currents flowing in the rhythm of the alternating voltage of the applied signals, which add up vectorially in accordance with the direction of winding of the head winding 10 (see position of the flux points), so that a stray field arises in the gap area of the opening magnetic head 11 , depending on the flow direction magnetizes a magnetic tape 24 passing through the head mirror region of the magnetic head 11 .

In addition to the alternating current, a direct current flows through the head winding 10 of the magnetic head 11 , which is required for setting the operating point of the current sources 6 and 7 . Due to the opposite winding direction of the two partial windings of the top winding 10 , the partial direct fields are compensated for with the same direct currents ic1 and ic2. There can be no signal distortions in the playback signal due to a DC field magnetization of the magnetic tape. In addition, DC field erasure of the magnetic tape 24 does not occur during a recording or playback operation.

Due to unavoidable circuit asymmetries, which can also be due to temperature, the direct currents ic1 and ic2 of the current sources 6 and 7 assume different values, so that the partial direct fields in the winding 10 of the magnetic head 11 are no longer canceled and thus become the ones mentioned Signal distortion and / or erasure comes.

For offset compensation of the direct currents ic1 and ic2, the operational amplifiers 17 and 20 measure the voltages dropping across the resistors 14 and 15 and compare them with the reference voltage output by the reference voltage source 22 . In the event of changes in the voltages falling across the resistors 14 and 15, the operational amplifiers 17 and 20 regulate the voltages at the control inputs of the current sources 6 and 7 to a value which corresponds to the set reference current (ic1 = Uref / R14 or ic2 = Uref / R15) necessary is. The quiescent current setting of the two current sources 6 and 7 is thus carried out by two DC control loops, the size of the reference voltage determining the size of the two DC currents ic1 and ic2. The two RC combinations R16 / C18 and R19 / C21 are used to integrate the voltages dropping across the two resistors 14 and 15 , since the circuit arrangement is only intended to compensate for the DC component. The limit frequency of the two RC combinations R16 / C18 and R19 / C21 may be around 100 Khz, for example, so that there is a resistance value of approx. 1 kOhm for resistors R16 and R19 and a capacitance value of approx 1 nF results. In the implementation of the basic circuit, there is the possibility of using operational amplifiers with current or voltage output.

In order to reduce the amount of circuitry, efforts are made to use only one operating voltage source. FIG. 2 shows a specific circuit design of the basic circuit shown in FIG. 1, which only requires an operating voltage. The signal which can be removed from the rotor winding 5 is fed to base connections of transistors 25 and 26 , the emitter connections of which are connected to ground potential via the resistors 14 and 15 . Terminal 8 is connected to the collector terminal of transistor 25 , terminal 9 to the collector terminal of transistor 36 and terminal 12 to terminal 13 . Instead of the two operational amplifiers 17 and 20 , the emitter voltages dropping across the resistors 14 and 15 are fed via the resistors 16 and 19 to the base connections of transistors 27 and 28 , the emitter connections of which are connected to one another and are connected to ground potential via a resistor 29 . The collector terminal of Tran sistor 27 is connected to the base terminal of transistor 25 and the output of a current source 30 . Due to the circuit symmetry, the collector terminal of transistor 28 is connected in a corresponding manner to the base terminal of transistor 26 and the output of a current source 31 . The inputs of the current sources 30 and 31 are connected to the positive potential (terminal 13 ).

In the circuit arrangement of FIG. 2, the transistors 25 and 26 take on the function of the current sources 6 and 7 shown in FIG. 1, which deliver the response currents ic1 and ic2 to the two partial windings of the head winding 10 of the response magnetic head 11 . The quiescent currents ic1 and ic2 over the collector-emitter paths of the two end transistors 25 and 26 are set with the voltage across the resistor 29 , wherein

ic1 = [Vbe27 + (Ie1 + Ie2) / R29] / R14

ic2 = [Vbe28 + (Ie1 + Ie2) / R29] / R15

is. Vbe27 and Vbe28 therein are the base-emitter voltages of transistors 27 and 28 and currents Ie1 and Ie2 are the emitter currents through emitter resistors 14 and 15 . The transistors 27 and 28 should be equal to a few tenths of a millivolt in terms of their base-emitter voltages. The end transistors 25 and 26 only have to have approximately the same high-frequency properties; a pairing of the end transistors 25 and 26 is not necessary.

The current sources 30 and 31 are designed as constant current sources; they can each be modeled by resistance.

Claims (8)

1. Circuit arrangement for recording signals on a magnetic carrier ( 24 ) with two current sources ( 6 , 7 ) that can be controlled by the signals to be recorded, for delivering recording currents to the center-tapped winding ( 10 ) of a recording magnetic head ( 11 ), two the current sources ( 6 , 7 ) associated resistors ( 14 , 15 ), via which currents emitted by the current sources ( 6 , 7 ) flow, and a device ( 16 to 21 ) for amplifying the difference between voltages dropping across the resistors ( 14 , 15 ) a reference voltage (Uref) at which the outputs of the device ( 16 to 21 ) are connected to control inputs of the two current sources ( 6 , 7 ). 2. Circuit arrangement according to claim 1, characterized in that the voltages falling across the resistors ( 14 , 15 ) are subject to integration 3. Circuit arrangement according to claim 1, characterized in that the circuit arrangement is provided for recording signals on a magnetic carrier and
contains a first and a second transistor ( 25 , 26 ),
in which emitter connections are connected to a first fixed potential via a first and second resistor ( 14 , 15 ),
at which basic connections the signal to be recorded is supplied and
in which the collector terminals of a Aufsprechmagnetkopfes (11) are respectively connected to ends of the winding provided with a center tap (12), winding (10) connected to said center tap (12) is located at a second fixed potential (13), and
contains a third and fourth transistor ( 27 , 28 ) in a differential amplifier circuit,
at which base connections a signal which can be taken off at the emitter connections of the first and second transistor ( 25 , 26 ) is fed in and
which collector connections are each connected to a base connection of the first and second transistors ( 25 , 26 ). 4. Circuit arrangement according to claim 3, characterized in that the emitter connections of the third and fourth transistors ( 27 , 28 ) are connected to one another and are connected to the first fixed potential via a third resistor ( 29 ). 5. Circuit arrangement according to claim 3, characterized in that the collector connections of the third and fourth transistor ( 27 , 28 ) are each connected to the output of a constant current source ( 30 , 31 ). 6. Circuit arrangement according to claim 3, characterized in that between the emitter connections of the first and second transistors ( 25 , 26 ) and the base connections of the third and fourth transistors ( 27 , 28 ) in each case a resistor ( 16 , 19 ) is inserted and that The emitter and the base connection of both the third and fourth transistor ( 27 , 28 ) are connected to a capacitor ( 18 , 21 ). 7. Circuit arrangement according to claim 3, characterized in that the signal to be recorded is fed via an inductive transformer ( 2 ) to the base connections of the first and second transistors ( 25 , 26 ). 8. Circuit arrangement according to claim 7, characterized in that in the line path of a rotor winding ( 5 ) of the inductive transformer ( 2 ), a capacitor ( 23 ) is inserted.