Tuner
Section
Steep Quieting Slope
The
quieting slope specification measures a tuner's ability to provide good
signal-to-noise performance under actual operating conditions. it's a far more
reliable indication of performance quality than the IHF (Institute of High
Fidelity) sensitivity figure often quoted as the prime specification to
consider when evaluating an FM tuner.
The
IHF figure gives only the number of microvolts necessary for minimum quality
reception. A signal with 3% distortion and noise (30 dB quieting) hardly
qualities as high fidelity. A signal-to-noise ratio in excess of 50 dB (the
revised 1975 IHF specification) is generally recognized to be necessary for high quality listening.
It is most important then, to examine a receiver's ability to quiet quickly
beyond the 30 dB quieting point.
Quieting
slope sensitivity figures measure the signal-to-noise ratio in the crucial five
to 500 microvolt range, where the majority of usable broadcast signals fall.
The steeper the slope, the quieter, and therefore the more listenable the
station.
Highly Sensitive and Selective RF Front End
Superior
selectivity is assured by a five-gang tuning capacitor in the Marantz 2325 and
2275 and four-gang in the 2250B. A triple-tuned RF interstage on Models 2325
and 2275 and a dual-tuned RF interstage on Model 2250B provide excellent image
and spurious response rejection.
Marantz
FET RF amplifiers and mixer stages provide excellent spurious signal rejection
and extremely low noise operation that results in excellent quieting
sensitivity.
Phase Loced Loop FM Stereo Demodulator
The
Phase Locked Loop (PLL) design was developed originally to provide a state-of-the-art communication system for
the space industry. Today the same
technology is used in all Marantz tuners and receivers to assure you of low
distortion,excellent stereo separation and superior noise rejection.
PLL
circuitry positively locks to the stereo pilot signal broadcast by a FM
station. This precise "phase lock" is absolutely necessary for high
performance in the stereo demodulation process. It enables the multiplex
demodulator to separate the stereo channel information from the FM multiplex
signal with more accuracy and less distortion than multiplex demodulators using
other designs.
In
addition, PLL is dependent on pilot phase and not on pilot amplitude, making it
less susceptible to false triggering from various types of noise interference.
Ceramic IF Filters
The
performance of an FM tuner is determined to a great extent by the performance
of its Intermediate Frequency (IF) amplifier. The ideal IF amplifier should
accept the desired band of frequencies with minimum phase distortion, while
rejecting all adjacent frequency signals.
Marantz
stereo receivers feature IF amplifiers consisting of ceramic filters, whose
characteristics produce a 200 kHz passband that's linear in phase. This
eliminates a major source of high frequency distortion and of loss of stereo
separation. Sharp cut-off slopes improve the tuner's rejection and selectivity
characteristics, permitting clear reception even when stations are closely
spaced.
Positive FM Muting
FM
tuning is made completely noise-free by a special parametric-type muting
circuit. The circuit responds to three characteristics of the FM signal: RF
noise level, RF signal strength and DC offset at the ratio detector, thus
assuring positive muting of the audio signal even under the most adverse
conditions.
FM Dolby De-Emphasis Network
Today
there are more than 100 FM stations throughout the U.S. broadcasting with a
Dolby Noise Reduction System, and others are sure to follow. To help you
recieve the clean, quiet FM reception promised by these Dolbyized broadcasts,
Marantz Models 2325, 2275, and 2250B incorporate a built-in 25 microsecond
Dolby FM equalization circuit that provides complete de-emphasis compatibility
when used with a Dolby Noise Reduction system.
(NOTE:
Model 2325 also has a complete Dolby Noise Reduction system built-in)
Noise
from a Dolbyized FM broadcast can be reduced approximately 12 dB by changing
the de-emphasis curve from 75 to 25 microseconds and utilizing the Dolby
system. This is the equivalent of reducing the noise power of a received FM
broadcast sixteen times below normal.
Dolby
encoding allows an FM station the choice of operating with significantly
reduces distortion, while still improving signal-to-noise ny approximately 9 dB
- or of broadcasting a signal that's effectively double in strength with a
signal-to-noise improvement of approximately 12 dB.
PREAMPLIFIER
SECTION
Flexible Tone Controls
The
more flexible the tone controls, the more accurately you can adjust for
non-linearities in frequency response caused by speakers, speaker placement,
room acoustics of the program source itself. The
tone control system in Marantz Models 2325, 2275 and 2250B features a
sophisticated five-position tone turner/mode switch for versatile bass,
midrange and treble control. This eliminates a major shortcoming of
conventional tone controls - their tendency to affect too wide a band of
frequencies. Optional frequency turnover points limit the effect of the bass
and treble controls to just the desired range.
The
advantages can be illustrated by a practical example: Boosting the low bass
(under 100 Hz) to compensate for a deficiency in room acoustics. Most
conventional tone control, even if capable of supplying the boost, will also increase the output in the 300 Hz
to 1000 Hz region. With the turnover point set at 250 Hz on a Marantz receiver,
the bass control can provide the desired bass boost (or cut) up to the
frequency point of 250 Hz, and leave the frequency range above the point
essentially flat and unaffected.
This
flexible, easy-to-set system permits over seven million combinations of
repeatable tone control settings, enabling you to adjust for the desired tonal
balance in any listening environment.
High performance Phono Preamp
Low
noise and a wide dynamic range are of paramount importance in the circuit
design of a phono section.
The
three-stage, 40 dB gain amplifier built into Marantz receivers utilizes
feedback-equalized circuitry to maintain extremely low distortion.
the
use of close tolerance, stable components, such as tantalum input coupling
capacitors, low noise carbon film resistors, Mylar output coupling and
polystyrene-type equalization capacitors assures superior performance.
RIAA
equalization is precise - within +/-0,5 dB, from 20 Hz to 20 kHz - and under test in the 2325, the equivalent
noise input to the phono section measures a low 0,8 microvolts. The phono
overload point occurs at over 100 millivolts in the 2250B, and at over 125
millivolts in the 2325 and 2275. These figures result in a dynamic range
capability of greater than 96 dB.
A full Complement of Inputs and Outputs
In
addition to the standard phono and auxiliary inputs, two sets of tape inputs
and outputs are provided to facilitate copying from one tape deck to another.
Front panel dubbing jacks allow you to add a third tape deck without disrupting
any rear panel connections.
The
preamp-out/main-in jacks on the rear panel enable you to use the preamplifier
and amplifier sections independently. You get simplified connection of external
components such as noise reduction systems, equalizers and electronic
crossovers - and the ability to use the receiver's preamp section to drive a
separate power amplifier.
here's
another benefit: Connecting the preamp section directly to a tape deck enables
you to make specially equalized recordings by using the preamp's flexible tone
controls.
Power
Amplifier Section
Full Complementary Symmetry Output
Assures
higher stability, better linearity and lower distortion than the
quasi-complementary outputs used in the amplifier sections of most receivers.
Quasi-complementary
circuitry tends to generage high order harmonic distortion and is particularly
susceptible to crossover distortion. To reduce theses types of distortion,
manufactures increase the amount of feedback within the amplifier. Under actual
dynamic conditions, however, the amplifier with exessive feedback is prone to
higher transient distortion and also lower stability.
In
contrast, full complementary symmetry output circuitry requires less feedback
by incorporating positive and negative amplifiers which are balanced to
mirror-image each other's characteristics. This design produces exceptional
linearity, lower total harmonic distortion and lower intermodulation
distortion.
For
these excellent reasons, Marantz receivers feature full complementary symmetry
design, as used extensively in Marantz professional products.
Direct Coupled Power Output
Provides
wide power bandwidth, excellent low frequency transient response and improved
damping fators.
Early
transistorized power amplifiers featured one of two types of output design. A
transformer or a capacitor was incorporated between the power output stage and
the speaker system. However necessary this was for proper output-to-speaker
coupling, it tended to limit low frequency power response or to cause degrading
phase shift, and thus impair sound accuracy.
Today's
more advanced technology has eliminated the need for coupling transformers and
capacitors and the sound inaccuracies they can cause.
The
sophisticated direct coupled output stages used in Marantz amplifiers assure
you of extremely high damping factors at low frequencies and the best possible
low frequency response.
Heavy-Duty Power Supply
High
reserve power supply sections and power output circuitry ensure that Marantz
receivers will continue to meet specifications through years of steady
performance.
A
massive power transformer forms the heart of a dual-balanced positive and
negative power supply that symmetrically powers the amplifier stages. large
capacity electrolitic capacitors assure high energy power reserves, while
massive heat sink promote highly reliable, long-term operation even under full
power output conditions.
Specifications
Rated Power
Output: 125 Watts (Minimum Continuous
Watts per Channel, Both Channels Driven)
Power Band: 20 Hz to 20 kHz
Total Harmonic
Distortion: 0,1%
Load Impedance: 8 ohms
I M Distortion (IHF
Method, 60 Hz and 7 kHz mixed 4:1 at Rated Power Output): 0,1%
Damping Factor (at 1
kHz): 70
Main
Inputs Sensitivity/Impedance: 1,0 V/55 kΩ
Frequency Response
(at 1W Output, 20 Hz to 20 kHz): ±20 dB
Pre-Amplifier
Section
Phono
Dynamic Range (Ratio
of Input Overload to Equivalent Input Noise):
96 dB
Equivalent
Input Noise (RMS, 20 Hz to 20 kHz): 1,5 μV
Input
Sensitivity and Impedance: 1,8 mV/47 kΩ
Frequency Response
(re. RIAA, 20 Hz to 20 kHz): ±0.5 dB
High Level Inputs
(Aux and Tape)
Input
Sensitivity and Impedance: 180 mV/100 kΩ
Output Impedance
Tape record: 200
Pre-Out: 900
Tone Controls
Bass: ±12 dB (50 Hz)
Mid: ±6 dB (700 Hz)
Treble: ±12 dB (15 kHz)
AM/FM SPECIFICATIONS
Quieting
Slope (Mono) 30 dB Quieting: 1,8 μV (10,3 dBf)
5 μV (19,2 dBf) : 55 dB
10 μV (25,2 dBf) : 60 dB
50 μV (39,2 dBf) : 70 dB
1000 μV (65,2 dBf) : 75 dB
Distortion
at 1000 μV (65 ,2 dBf, Mono)
100 Hz : 0,25%
1000 Hz : 0,15%
6000 Hz : 0,3%
Distortion
at 1000 μV 965,2 dBF, Stereo)
100 Hz : 0,35%
1000 Hz : 0,3%
6000 Hz : 0,5%
Distortion at 50 dB
Quieting (Mono and Stereo)
1000 hz : 0,6%
Hum
and Ni=oise at 1000 μV (65,2 dBf)
Mono : 70 dB
Stereo : 60 dB
Frequency Response
30 Hz to 15 kHz
Mono : ±1,0 dB
Stereo : ±1,5 dB
Capture Ratio
at 100
μV (45,2 dBf) : 1,8 dB
at
1000 μV (65,2 dBf) : 1,25 dB
Alternate
Channel Selectivity: 80 dB
Spurious Response
Rejection: 100 dB
Image Response
Rejection: 100 dB
IF Rejection
(Balanced): 100 dB
AM
Suppression at 100 μV (45,2
dBf): 62 dB
Stereo Separation
100 Hz : 38 dB
1000 hz : 42 dB
10 kHz : 30 dB
Pilot (19 kHz)
Rejection: 65 dB
AM
usable Sensitivity: 20 μV
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