FR2708807A1 - Electrical signal amplifier - Google Patents

Abstract

The invention relates to an electrical signal amplifier (1) which consists of a circuit comprising an input (E), an output (S), amplification means (A1 to A4) and power supply means (+Vcc, -Vcc), which amplification means (A1 to A4) comprise active elements comprising at least one transistor, each of these active elements comprising an input terminal and two terminals (A, B) called, in general, active terminals, one (B) of which active terminals is linked to a DC power supply voltage via a resistor (R1, R4) called power supply resistor. It is characterised in that the active elements of each intermediate stage have one (A) of their active branches (A, B) linked to the mid point (M) by at least one passive element (R2, R3) called auxiliary element, which, with the power supply resistor, controls an input voltage, called intermediate voltage, for the following stage.

Description

 The invention relates to an electrical signal amplifier.

 It relates more particularly but not exclusively to low frequency amplifiers for amplifying audible frequency signals.

 The amplification of electrical signals representing in particular a sound message requires, on the one hand, to limit the deformation of the signal within given limits and, on the other hand, to preserve the dynamics of the signal.

Conventionally, an amplifier consists of an electrical circuit comprising
an input on which is electrically connected the control source from which a signal to be amplified originates,
an output connected to an electric load exploiting the amplified signal,
- means of amplification and
power supply means supplying the energy necessary for the amplification means.

 These amplification means consist of active elements comprising at least one transistor, each of these active elements comprising an input terminal and two so-called generally active terminals, one of which is connected to a DC supply voltage through a resistor. said food.

 These so-called active terminals are more generally called collector or transmitter but depending on the type of transistors, for example in the case of so-called field effect transistors, they can also call drain or source.

 Classically, these amplification means are arranged in at least two amplification stages including a so-called input stage.

 Still in a conventional manner, the stages are each constituted by two active elements mounted symmetrically around a midpoint to form two branches of amplification known as positive and negative.

 Each intermediate stage up to the final stage has its input called intermediate input which takes the signal to be amplified on the previous 1 stage providing meanwhile an output signal said intermediate.

 Conventionally, the input stage comprises two transistors of the field effect type, called TEC, each provided with a trigger, drain and source electrode, which transistors TEC are mounted symmetrically about a midpoint with their electrodes called triggers connected to the input terminal of the amplifier to which the signal to be amplified and their drains connected to a DC voltage supply source are applied at least indirectly through a resistor.

 In the circuits known to date, and in particular in symmetrical assemblies, one of the active terminals of an active element is connected directly, without passive component, to one of the terminals of the other active element and the signal of intermediate input is taken directly on an active component, such as a transistor, which is the case of so-called differential or current mirror assemblies.

 The equilibrium of the assembly between two active elements is therefore directly dependent on each active element.

 These active components, even if they are said to be identical, however, have characteristics that remain very variable, which influences the amplification of the signal and its transmission through the stages.

 Also, in these circuits, the DC current of the bias circuits is mixed with the amplified signal.

 Indeed, in these known circuits using field effect transistors, the polarization voltage thereof is injected at the level of the final stage.

 To remedy these drawbacks in particular of stability, it is known to use assemblies implementing a so-called global feedback loop which draws at the output of the amplifier a representative fraction of the amplified signal to reinject it substantially on 1 input of the amplifier to generate a servo and a correction of the distortions induced by the components and their thermal drifts.

 If this global feedback loop makes it possible to reduce the signal distortion, it unfortunately reduces the dynamics of the signal.

 Experience shows that, if the deformation of the signal remains contained within predetermined limits, it is not really perceived by the listener.

 On the other hand, if the dynamic is affected, it is very badly felt by the listener.

 One of the results that the invention aims to obtain is an amplifier of the aforementioned type which remedies these drawbacks and in particular has a great dynamic.

 For this purpose, it relates to such an amplifier of the above-mentioned type, in particular characterized in that the active elements of each intermediate stage each have one of their active branches connected to the mid-point through at least one passive element called auxiliary element such as a resistor said auxiliary resistance controlling with the so-called supply resistance carried by the other branch activates the intermediate input voltage for the next stage so that this intermediate input voltage depends directly on a mathematical relationship between this auxiliary resistance and the so-called power supply resistance.

The invention will be better understood using the following description given by way of non-limiting example with reference to the attached drawing which represents
- Figures 1 to 3: simplified diagrams of the invention in different embodiments.

 Referring to the drawing, it can be seen that in order to amplify a so-called low frequency signal which notably represents an acoustic signal, an amplifier 1 is used.

Classically, an amplifier 1 consists of an electrical circuit comprising
an input E on which is connected electrically a control source from which a signal to be amplified originates,
an output S connected to an electric load 2 exploiting the amplified signal,
amplification means A1 to A4 and supply means + Vcc, -Vcc supplying the energy required for the amplification means.

 These amplification means A1 to A4 comprise active elements BI to B4 comprising at least one transistor, each of these active elements comprising an input terminal and two terminals A, B said, generally active, one of which ( B) active terminals is connected to a supply voltage + Vcc, -Vcc continues through a resistor R1, R4, R5, R6 said supply.

 Classically, these amplification means are arranged at least in two amplification stages E1, E2 including a so-called input stage.

 Still in a conventional manner, the stages each consist of two active elements B1, B2 and B3, B4 mounted symmetrically around a midpoint M to form two branches, positive and negative.

 Each intermediate stage up to the final stage has its input D1 to D4 said intermediate input which takes the signal to be amplified on the previous stage which provides meanwhile an output signal said intermediate.

Conventionally, the input stage comprises two transistors
T1, T2 of the field effect type, called TEC, each provided with a trigger electrode, a drain and a source, which transistors TEC are mounted symmetrically around a midpoint M with their electrodes known as gachettes, connected to the input terminal of the amplifier to which the signal to be amplified is applied as well as a polarization voltage Pol-, Pol +.

 According to the invention, the active elements B1 to B4 of each intermediate stage each have one (A) of their active branches A, B, connected to the middle point M through at least one passive element R2, R4 called auxiliary such as a resistor said auxiliary resistance controlling with the resistor R1, R2 said supplying the intermediate input voltage for the next stage so that this intermediate input voltage depends directly on a mathematical relationship between this auxiliary passive element and the resistance called feeding.

According to the invention, the control source 10 is connected to the gate of the transistors TEC by a decoupling component
C1, C2 such a capacity.

 This avoids mixing the bias voltage of the field effect transistors with the signal to be amplified.

 Thus, each intermediate stage is counter-reacted strongly and almost independently of the other stages.

We obtain
- good quality for each floor provided that we choose very precise passive components and,
- a great dynamic.

 Thus, referring to FIG. 1 and examining the positive branch of the amplifier with its transistors T1, T3 and assuming that the coefficient ss of the intermediate active element T3 is large, it can be considered that the intensity which passes through the input transistor T1 and its supply resistors R1 and auxiliary R2 is the same.

 As a first approximation, it can be considered at low frequency that the alternating signal at the input point E of the amplifier is found entirely on the terminal A of the input transistor T1.

On the other terminal B of the same input transistor, it is multiplied by the ratio of the resistances of the input transistor
R1 / R2 and it is this AC voltage found on the supply terminal C of the intermediate stage.

The voltage amplification of the first stage is therefore
RI / R2.

 Both floors work in class A.

 The exact polarization Pol + is set so that the DC voltage across the auxiliary resistor R2 of the input transistor T1 is such that for the maximum AC input voltage, the intensity in the supply resistor R5 of the stage intermediate never vanishes and even remains significantly higher than zero Volt, this to reduce the distortion.

So, if we write the equations of the tensions at the points
A, B, C above, we have
Vcc - Vb = Va (R1 / R2)
Vcc - Vc = (Va (R1 / R2)) - 0.7
A signal Am sin Qt is applied at point E.

Let Am be the maximum amplitude of the sinusoidal signal at point E.

It is necessary that for sin Qt = -1
Vcc - Vc = ((Va - Am) (R1 / R2)) - 0.7> O, that is
Va> Am + (0.7 (R2 / R1))
The intensity in the auxiliary resistor R2 is chosen as a function of the input transistors T1 or T2 and must be large relative to the base current of the transistors T3 (T4).

We can calculate
R2 = Va / intensity chosen in T1
For the first stage to amplify in voltage, the power supply resistor Ri must be greater than the auxiliary resistor R2, but this power supply resistor R1 must not be chosen too large with respect to the auxiliary resistor R2 so that the The amplitude across the supply resistor R5 of the transistor of the next stage is not too great with respect to the supply voltage.

We can take for example: R1 / R2 ~ 1.2 to 1.5
let V be the alternating voltage on the bases of the transistors of the second stage T3 (T4), we have
I1 = (Vcc - Vb + v - 0.7) / R5
As there is symmetry and the alternating voltages on the bases are in phase,
I2 = (Vcc - Vb - v - 0.7) / R5 ===> I1 + I2 = (2 (Vcc - Vb) - 1,4) / R5 = Cte, therefore I1 + I2 = Cte and Vs = ( 1i - I2) .R7, so
Vs = 2.v.R7 / R5 with I1 and I2, the current flowing through the branches connected to the midpoint of the second stage transistors.

The voltage application of the second stage is therefore 2.R7 / R5 and the theoretical maximum voltage amplification of the circuit is (R1 / R2). (2.R7 / R5)
In fact, since the coefficient ss of the transistors T3 (T4) is not infinite, the amplification is in practice less than the value found.

 The intensity in T3 (T4) is chosen as a function of the transistors used and the application so that the intensity in T3 (T4) divided by the coefficient ss of the transistors is very much less than the intensity which passes through T1 ( T2).

 It is therefore possible to calculate the resistance R5 and to select the resistor R7 to obtain the desired voltage amplification for the assembly.

R5 = ((Va.R1 / R2) - 0.7) / Intensity chosen in T3 (T4)
During a positive pulse, at most when the transistor T3 is saturated
Vcc> (Vcc - Vc) + Vs, either
Vcc> ((Va + Am) R1 / R2) - 0.7 + ((R1 / R2) .2Am.R7 / R5)
On the assembly shown in FIG. 2, use is made of a third current amplification stage using MOSFET transistors.

 The assembly of Figure 3 is more complete and uses the assembly known generally as the "cascade mounting".

 The transistors at the last stage are connected in parallel in order to increase the quality of the amplifier and to improve the heat dissipation produced at the final power stage.

Claims (2)

 1. Amplifier (1) of electrical signals which consists of a circuit comprising  an input (E) on which is electrically connected a control source (10) from which a signal to be amplified originates,  an output (S) connected to an electric charge exploiting the amplified signal,  amplification means (A1 to A4) and  supply means (+ Vcc, -Vcc) supplying the energy required for the amplification means,  which amplification means (A1 to A4)  - comprise active elements (B1 to B4) comprising at least one transistor, each of these active elements comprising an input terminal and two terminals (A, B) said, generally active, one (B) of which active terminals is connected to a DC supply voltage through a so-called resistor (RT, R4) and,  are arranged at least in two amplification stages (E1, E2), including an input stage (E1), with each intermediate stage up to the final stage which has its input (D1 to D4), said intermediate input which picks up the signal to be amplified on the preceding stage, which in turn provides an intermediate output signal,  said input stage comprising two field effect type transistors (T1, T2), called TEC, each provided with a trigger, drain and source electrode, which TEC transistors are symmetrically mounted around a point medium (M) with their electrodes called triggers, connected to the input terminal of the amplifier to which the signal to be amplified is applied as well as a polarization voltage (Pol-, Pol +),  this amplifier being CHARACTERIZED in that the active elements (B1 to B4) of each intermediate stage have one (A) of their active branches (A, B), connected to the midpoint (M) by at least one passive element (R2, R3) said auxiliary said a so-called power supply a so-called intermediate input voltage for the next stage so that this intermediate input voltage depends directly on a mathematical relationship between this passive element and the so-called power supply resistor .  2. Amplifier according to claim 1 characterized in that the control source is connected to the trigger of the transistors TEC by a decoupling component.