Philips AN1651 manual Fiber Optic Receiver for Low Frequency Data Figure

Page 14

Philips Semiconductors

Application note

 

 

 

Using the NE/SA5234 amplifier

AN1651

 

 

 

 

 

 

 

+4.5V

 

 

 

 

 

10kΩ

10kΩ

 

 

 

 

 

 

10kΩ

 

 

4

 

 

 

 

 

 

NE5234

 

+

±

16

12

 

 

 

 

 

 

 

 

 

19

 

 

100kΩ

 

 

 

 

 

 

R3

 

 

 

 

 

 

 

 

 

+

 

 

+

 

 

 

12kΩ

1μF

A1

 

 

A2

 

 

 

 

 

±

 

 

±

+4.5V

 

 

 

2.2kΩ

 

 

 

RA

 

 

11

 

 

 

 

 

 

 

MIC

 

 

 

 

18kΩ

 

 

 

 

 

0.15μF

 

 

SENS.

 

NE578

 

220Ω

 

 

 

 

 

 

 

 

 

ADJ.

 

 

4.7μF

 

 

 

 

 

25kΩ

 

 

 

 

 

 

 

 

RS

 

10

 

 

D2

 

 

0.47μF

 

 

 

 

 

 

 

 

 

 

Ct

 

D1

 

25kΩ

 

 

1nF

 

 

 

 

 

 

 

 

+

 

 

±

 

 

 

9

 

A3

 

 

A4

 

8

 

RD

±

 

 

+

4.2V

7

 

 

10kΩ

 

 

 

 

 

 

OFF

ON

 

 

 

 

 

 

 

 

 

 

X1

 

11

2.2MΩ

0V

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

40.2kΩ

 

 

 

 

 

 

 

 

SL00651

Figure 23. VOX Audio System

Other critical parameters in this type of circuit are the attack and decay times of the RC network which controls the operation of the voice operated switch. Attack time determines how quickly the circuit activates after a quiet period, and the decay time sets how long the transmitter channel stays active between words. It is important to reach an optimum balance between the two time constants in order to allow unbroken transmissions of good quality and no lost syllables. A 100 to 1 attack/decay ratio is used in this particular application and this is primarily set by the value of RA and RD. A typical delay of two seconds is easily accomplished. Due to extremely high input impedance of the buffer stage A3, RD may be in the 1 to 2MΩ range allowing a reasonable value of storage capacitor to be used.

The Audio Channel

Audio input from the preamplifier, A1, is fed directly to Pin 14 of the NE578 compandor. Referring to Figure 24, which shows the internal diagram of the device, it can be seen that this is the compressor portion of the NE578. There is the option in this system to operate either in a 2:1 compressor mode or an automatic level control mode, (ALC). The compressor mode simply makes a 2:1 reduction in the amplitude dynamic range of the input signal and brings it up to the chosen nominal 0dB output level which is programmable from 10mVRMS to 1VRMS. In this particular example it is programmed for a 0dB level of 0.42VRMS which is approximately 1VP-P. This allows for a standardized output level with good characteristics for FM modulation where peak deviation must be controlled. Figure 25 shows the input-output characteristics of the compressor and ALC.

The compressor also has an attack time determined by capacitor C6 on Pin 11. Attack time is 10k * C6, decay time equals four times this value. An auxiliary amplifier stage is used following the NE578 in order to allow bandwidth and special forms of equalization to be implemented. Note that 2:1 compression in a transmission will enhance the channel dynamic range and may be used with no further processing at the receiver, but feeding the received signal through the complimentary 2:1 expandor will achieve even greater enhancement of the recovered audio. The NE578 contains both operations in the same package. Please refer to Philips Semiconductors applications note AN1762 by Alvin K. Wong for complete information on these compandor circuits using the NE578.

Fiber Optic Receiver for Low Frequency Data (Figure 26)

This application makes use of the NE/SA5234 to detect photo-optic signals from either fiber or air transmitted IR (Infra-red) pulses. The signal is digitally encoded for the highest signal-to-noise ratio. The received signal is sensed by an IR photo diode which has its cathode biased to half the supply voltage (2.5V). The first gain stage is configured as a transimpedance amplifier to allow conversion from the microampere diode current signals to a voltage output of approximately 10mV0-P. The second stage provides a gain-of-ten amplifier to raise this signal level to 1V peak amplitude. This stage is directly coupled from the preamplifier stage in order to provide the necessary common-mode voltage of 2.5V. Its gain control network is capacitively coupled to prevent DC gain as is required in single supply configurations. Since this is essentially a pulse gain stage, low frequency gain below the signal repetition rate is not needed. The third stage acts in a limiting amplifier

1991 Oct

14

Image 14
Contents AN1651 Input Stage SummaryII. Detailed Description Internal Frequency Compensation III. CharacteristicsIntermediate Amplifier and Output Stage Figure NE5234 Closed Loop Gain vs Frequency IV. Noise Referred to the Input Guide Lines for Minimizing NoiseVI. Multiple Stage Considerations Amplified Noise = 160μVRMSVII. LOW Harmonic Distortion THD vs Supply Voltage for 1VRMS OutputSlew Rate Response VIII. GAIN-BANDWIDTH VS Closed Loop FRE- Quency ResponseIX. LOOP-GAIN Non-Inverting Stage Biasing XI. ProceduresSingle Supply Operation Strain Gauge Amplifier To 20mA Current Loop Applications ExamplesInstrumentation Active filters Communications and AudioActive Filters Fiber Optic Receiver for Low Frequency Data Figure References NE578NE570/571/SA571 System Level Half Bridge Servo

AN1651 specifications

The Philips AN1651 is a highly regarded car audio speaker offering an impressive balance of sound quality and performance. Designed primarily for the car audio enthusiast, this model showcases what modern engineering can achieve in automotive sound systems.

One of the main features of the AN1651 is its dual cone structure that produces clear and rich sound across various frequencies. This design aims to enhance both low and mid-range sounds, ensuring that music is delivered with clarity and precision. Whether you're listening to rock, pop, or classical, the AN1651 is built to convey the nuances of music effectively.

The speaker boasts a peak power handling capability of up to 240 watts, which allows for immersive sound experiences without distortion, even at higher volumes. This capability means that the AN1651 can handle the punchy bass lines typical in many contemporary music genres, making it a popular choice among bass enthusiasts.

Philips also incorporates their innovative technologies, such as a reinforced polypropylene cone. This material enhances sound quality by providing better rigidity while remaining lightweight. The result is a responsive speaker with reduced resonance, contributing to more accurate audio playback. Furthermore, the butyl rubber surround is designed to withstand wear and tear, ensuring durability and longevity in automotive conditions.

The AN1651 also features a sensitivity rating of 91 dB, allowing it to produce powerful sound output even with moderate power input. This feature makes it an ideal choice for vehicles with smaller amplifiers or factory stereo units, as it ensures an enjoyable listening experience without requiring significant upgrades.

In terms of installation, the AN1651 is designed for versatility. Its size makes it compatible with a wide range of vehicles, and the mounting accessories included facilitate an easy and secure fit.

With a smart aesthetic that blends well with various car interiors, the Philips AN1651 speaker is more than just a functional audio component; it is a stylish addition to your vehicle.

In conclusion, the Philips AN1651 combines advanced technologies and thoughtful design to deliver a rich audio experience that car enthusiasts will appreciate. Whether for casual listening or serious audio enjoyment, this speaker meets diverse audio needs, proving to be a valuable investment for any car audio system.