Low Noise Microphone Preamplifier

This is a design for a low noise microphone preamplifier, which is ideally suited to low impedance (600 Ohm nominal) microphones. One limitation is that it is not balanced, which is not a problem in a home recording environment, but will allow the mic lead (and case) to pick up noise with long cable runs or in a hostile environment.

As shown, it is not really suitable for professional work (although it has been used on stage in its unbalanced form with good results), but the addition of a 1:1 microphone transformer on the input will convert it into a balanced preamp with very high performance. In many cases, a transformer will actually outperform active balancing circuits, because there is (or should be) no ground reference. The shield of the balanced cable must be earthed of course, but in my experience with live music and studio work, less noise is picked up if the internal wiring is floating.

It is most regrettable that good mic transformers are rather hard to come by, and are expensive. If you happen to have a suitable one in your junk box, give it a try with this circuit - I doubt that you will be disappointed with the result. I have used this circuit in Front-of-House, fold back (monitor) and studio mixers, and managed to obtain excellent results - I still have a little 6 channel mixer (which I use only occasionally now) using this circuit, and have never been even slightly tempted to replace it with even the best of op amps

This is the figure;

It requires a well regulated (or extremely well smoothed) supply voltage of 30V, and will typically be able to supply a maximum output level of around 7V RMS allowing for typical component spreads. With the component values shown, impedance matching is correct for a 600 Ohm mic, and the gain is about 40. Note that this is far too high to use with any microphone for close-miked vocals or instrument amplifiers, but is suitable for normal speech.

By making the SET GAIN resistor a 50k linear pot, the gain can be varied from virtually 0 up to a maximum of 40 (32dB), with low noise and distortion at all settings. The output level from a well known brand of vocal mic has been measured at over 1 Volt peak-to-peak with loud singers, so the "conventional wisdom" of mics having low output is clearly wrong. For this reason, making the preamp with variable gain is almost an essential requirement.

The open-loop gain of this little circuit is about 3,400 - this is obtained by disconnecting the feedback resistor, and bypassing R5 with a suitably large value capacitor. All this from a single amplifying transistor !

Measurements taken when I was building lots of these show that the equivalent input noise was about -127dBm, so with a gain of 40dB, signal to noise ratio should be about 87dB relative to an output of 0dBm (approx 775mV). This is completely unattainable in practice, because of the noise from the microphone itself as well as other extraneous noises which cannot be eliminated.

Needless to say, the use of metal film resistors is a must to get the best possible noise performance. I'm not completely happy with the requirement for electrolytic capacitors, but for the impedances involved relatively large value caps are a must. Use of Low Leakage electros may be worth the effort, but I have not experimented with this option. I have used solid "tag" tanalum caps in this circuit, but they are (or were) revoltingly unreliable and I stopped using them after it was necessary to change every tantalum cap in a batch of about 20 small 8 channel stage mixers. I was not impressed !

Increasing Open-Loop Gain and Reducing Output Impedance

If you think it is worth the extra effort (which quite frankly I don't), the next version is interesting. The open loop gain of this configuration is now an astonishing 1,200,000 - or over 120dB from a single amplifying transistor. The op-amp acts as a unity gain buffer - basically a "high tech" version of the emitter follower in the previous circuit.

Although open loop gain, as well as output impedance and output drive capability are all improved, the noise figure can be expected to be slightly worse. It is also likely that although measurable distortion may be reduced, the preamp may lack musicality - that undefinable something that no-one has actually been able to quantify. IMHO this is very unlikely with this circuit, but one never knows.

Gain with the values shown remains at 32dB, and the op-amp should be powered from the +30V and 0V rails (i.e. NOT with a split supply - the voltage will be too high for the op-amp). The second version has not actually been built and used in earnest, but has been simulated and is a viable proposition - it can be expected to work as described without problems.

This is the figure:

Digital Volt Meter Theory

Digital of Volt Meter models gauging of DC or AC voltage in the form of number discrit in the place of deflection of continuing on a scale indicator needle like in analogue devices. In many directing usages with number is thing profiting because lessening read error of man and interpolation error, eliminates error paralaxtion, enlarges read speed and often complements output in the form of digital according to for processing and record-keeping hereinafter.

DVM is an instrument pledged and accurate which can be applied in many gauging usages in laboratory. Because development and retouching of modules integrated circuit (IC), scale, requirement of power and the price of DVM has decreased drastically so that DVM actively can compete to instrument of other conventional analogue, in portability and also price.

Quality Of DVM which is uppermost can be depicted by arising some of operation characteristics and performance characteristic that is typical. Specification of following not all applying at a certain instrument, but they really express valid information about this present condition:

1. Input ambit: from less lebih1, 000000 V to 1000, 000 V, with election of ambit automatically and indication of overload.

2. Accuracy of absolute equal to 0, 005% from read.

3. Stability line: short-range 0, 002% from read for period 24 hours; length reach 0, 008% read for period 6 month.

4. Resolution: inner 1 10 ranks 6 (1 micro uF can read at input ambit 1V).

5. Input characteristic: typical input resistance is 10 MOHM; input capacity is 40 pF.

6. Calibration: internal calibration standard enabling calibration doesn't base on measure circuit obtained from source of reference stabilized.

7. Output signals: shallow command enables output of towards printing unit ( printer) output BCD (Binary Coded Decimal = each decimal numbers of its(the number expressed with 4 beet) for digital processing or record-keeping.

DVM can be grouped through some categories:

a. DVM ramp ( ramp type DVM).

b. DVM merger type ( integrating DVM).

c. Balance DVM of continuant ( continues balance DVM).

d. DVM with approximate successively ( successive approximation DVM).

60W Guitar Amplifier

Resistor;

R1 6K8 1W Resistor

R2,R4 470R 1/4W Resistors

R3 2K 1/2W Trimmer Cermet

R5,R6 4K7 1/2W Resistors

R7 220R 1/2W Resistor

R8 2K2 1/2W Resistor

R9 50K 1/2W Trimmer Cermet

R10 68K 1/4W Resistor

R11,R12 R47 4W Wire wound Resistors

Capasitor;

C1,C2,C4,C5 47µF 63V Electrolytic Capacitors

C3 100µF 25V Electrolytic Capacitor

C6 33pF 63V Ceramic Capacitor

C7 1000µF 50V Electrolytic Capacitor

C8 2200µF 63V Electrolytic Capacitor (See Notes)

D1 LED Any type and color

D2 Diode bridge 200V 6A

Transistor;

Q1,Q2 BD139 80V 1.5A NPN Transistors

Q3 MJ11016 120V 30A NPN Darlington Transistor (See Notes)

Q4 MJ11015 120V 30A PNP Darlington Transistor (See Notes)

SW1 SPST Mains switch

F1 4A Fuse with socket

T1 220V Primary, 48-50V Secondary 75 to 150VA

Mains transformer (See Notes)

PL1 Male Mains plug

SPKR One or more speakers wired in series or in parallel

Total resulting impedance: 8 or 4 Ohm

Minimum power handling: 75W

This Figure is schematic about the amplifier;

Preamplifier parts:

P1,P2______________10K Linear Potentiometers

P3_________________10K Log. Potentiometer

R1,R2______________68K 1/4W Resistors

R3________________680K 1/4W Resistor

R4________________220K 1/4W Resistor

R5_________________33K 1/4W Resistor

R6,R16______________2K2 1/4W Resistors

R7__________________5K6 1/4W Resistor

R8,R21____________330R 1/4W Resistors

R9_________________47K 1/4W Resistor

R10_______________470R 1/4W Resistor

R11_________________4K7 1/4W Resistor

R12,R20____________10K 1/4W Resistors

R13_______________100R 1/4W Resistor

R14,R15____________47R 1/4W Resistors

R17,R18,R19_______100K 1/4W Resistors

C1,C4,C5,C6________10µF 63V Electrolytic Capacitors

C2_________________47µF 63V Electrolytic Capacitor

C3_________________47pF 63V Ceramic Capacitor

C7_________________15nF 63V Polyester Capacitor

C8_________________22nF 63V Polyester Capacitor

C9________________470nF 63V Polyester Capacitor

C10,C11,C12________10µF 63V Electrolytic Capacitors

C13_______________220µF 63V Electrolytic Capacitor

D1,D2____________BAT46 100V 150mA Schottky-barrier Diodes (see Notes)

Q1,Q3____________BC546 65V 100mA NPN Transistors

Q2_______________BC556 65V 100mA PNP Transistor

J1,J2___________6.3mm. Mono Jack sockets

SW1,SW2___________SPST Switches

This design adopts a well established circuit topology for the power amplifier, using a single-rail supply of about 60V and capacitor-coupling for the speaker(s). The advantages for a guitar amplifier are the very simple circuitry, even for comparatively high power outputs, and a certain built-in degree of loudspeaker protection, due to capacitor C8, preventing the voltage supply to be conveyed into loudspeakers in case of output transistors' failure.

The preamp is powered by the same 60V rails as the power amplifier, allowing to implement a two-transistors gain-block capable of delivering about 20V RMS output. This provides a very high input overload capability.

Technical data:

Sensitivity:

35mV input for 40W 8 Ohm output

42mV input for 60W 4 Ohm output

Frequency response:

50Hz to 20KHz -0.5dB; -1.5dB @ 40Hz; -3.5dB @ 30Hz

Total harmonic distortion @ 1KHz and 8 Ohm load:

Below 0.1% up to 10W; 0.2% @ 30W

Total harmonic distortion @ 10KHz and 8 Ohm load:

Below 0.15% up to 10W; 0.3% @ 30W

Total harmonic distortion @ 1KHz and 4 Ohm load:

Below 0.18% up to 10W; 0.4% @ 60W

Total harmonic distortion @ 10KHz and 4 Ohm load:

Below 0.3% up to 10W; 0.6% @ 60W

Treble control:

+9/-16dB @ 1KHz; +12/-24dB @ 10KHz

Brightness control:

+6.5dB @ 500Hz; +7dB @ 1KHz; +8.5dB @ 10KHz

Bass control:

-17.5dB @ 100Hz; -26dB @ 50Hz; -28dB @ 40Hz

12V Version of Preamplifier

This is a very quiet preamplifier, but is only suited to low impedance inputs - the noise figure degrades rapidly as the input impedance is increased. The design - in particular the collector current for Q1 - was based on the noise / current / impedance graphs for the Philips version of the BC549 - minor variations are likely with different transistors, or BC549 devices from other manufacturers.

The entire circuit is naturally Class-A, and with a gain of 32dB, has an output impedance of less than 100 Ohms. The recommended load impedance is 22k or greater, so it is quite capable of driving a set of tone controls or a fader. Buffering with a good quality opamp will naturally reduce output impedance (and also increases output drive capability and open-loop gain) as shown in the example in the figure.

The exact same design has also been used as a virtual earth mixer for the mix bus in mixers from 6 to 24 channels. The only change is to remove the 1k2 resistor at the input, and connect the mix bus directly. The optimum impedance must be retained for low noise, so for a 10 channel mixer, each channel should have an output resistance of 12k to 20k to the bus. Fewer channels require lower resistance and vice versa.

This is the figure;

The circuit seems to discourage people because of the single +30V supply. The up figure shows the resistor values needed to run the preamp from a 12V supply, but naturally the output voltage is dramatically reduced before clipping. I have included this version to demonstrate that lower voltage operation is possible, as this seems to be something that people want.