SA614AD/01,112 NXP Semiconductors, SA614AD/01,112 Datasheet - Page 9

SA614AD/01,112

Manufacturer Part Number

SA614AD/01,112

Description

IC FM IF SYSTEM LOW PWR 16-SOIC

Manufacturer

NXP Semiconductors

Datasheet

1.SA614AD01118.pdf (14 pages)

Specifications of SA614AD/01,112

Package / Case

16-SOIC (0.154", 3.90mm Width)

Function

FM IF System

Frequency

25MHz

Rf Type

Cellular, ASK, FSK

Secondary Attributes

RSSI Equipped

Mounting Style

SMD/SMT

Operating Supply Voltage

6 V

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 40 C

Operating Temperature (min)

-40C

Operating Temperature (max)

85C

Operating Temperature Classification

Industrial

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

Other names

935275282112
SA614AD/01
SA614AD/01

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inductances and capacitances, 3) radiated fields, and 4) phase shift.

Philips Semiconductors

input level, the limited signal will begin to dominate the regeneration,

and the demodulator will begin to operate in a “normal” manner.

There are three primary ways to deal with regeneration: (1)

Minimize the feedback by gain stage isolation, (2) lower the stage

input impedances, thus increasing the feedback attenuation factor,

and (3) reduce the gain. Gain reduction can effectively be

accomplished by adding attenuation between stages. This can also

lower the input impedance if well planned. Examples of

impedance/gain adjustment are shown in Figure 9. Reduced gain

will result in reduced limiting sensitivity.

A feature of the SA614A IF amplifiers, which is not specified, is low

phase shift. The SA614A is fabricated with a 10GHz process with

very small collector capacitance. It is advantageous in some

applications that the phase shift changes only a few degrees over a

wide range of signal input amplitudes.

Stability Considerations

The high gain and bandwidth of the SA614A in combination with its

very low currents permit circuit implementation with superior

performance. However, stability must be maintained and, to do that,

every possible feedback mechanism must be addressed. These

mechanisms are: 1) Supply lines and ground, 2) stray layout

As the system IF increases, so must the attention to fields and

strays. However, ground and supply loops cannot be overlooked,

especially at lower frequencies. Even at 455kHz, using the test

layout in Figure 3, instability will occur if the supply line is not

decoupled with two high quality RF capacitors, a 0.1 F monolithic

right at the V

electrolytic is not an adequate substitute. At 10.7MHz, a 1 F

tantalum has proven acceptable with this layout. Every layout must

be evaluated on its own merit, but don’t underestimate the

importance of good supply bypass.

At 455kHz, if the layout of Figure 3 or one substantially similar is

used, it is possible to directly connect ceramic filters to the input and

between limiter stages with no special consideration. At frequencies

above 2MHz, some input impedance reduction is usually necessary.

Figure 9 demonstrates a practical means.

As illustrated in Figure 10, 430 external resistors are applied in

parallel to the internal 1.6k load resistors, thus presenting

approximately 330 to the filters. The input filter is a crystal type for

narrowband selectivity. The filter is terminated with a tank which

transforms to 330 . The interstage filter is a ceramic type which

doesn’t contribute to system selectivity, but does suppress wideband

noise and stray signal pickup. In wideband 10.7MHz IFs the input

filter can also be ceramic, directly connected to Pin 16.

In some products it may be impractical to utilize shielding, but this

mechanism may be appropriate to 10.7MHz and 21.4MHz IF. One

of the benefits of low current is lower radiated field strength, but

lower does not mean non-existent. A spectrum analyzer with an

active probe will clearly show IF energy with the probe held in the

proximity of the second limiter output or quadrature coil. No specific

recommendations are provided, but mechanical shielding should be

considered if layout, bypass, and input impedance reduction do not

solve a stubborn instability.

The final stability consideration is phase shift. The phase shift of the

limiters is very low, but there is phase shift contribution from the

1997 Nov 07

Low power FM IF system

pin, and a 6.8 F tantalum on the supply line. An

quadrature tank and the filters. Most filters demonstrate a large

phase shift across their passband (especially at the edges). If the

quadrature detector is tuned to the edge of the filter passband, the

combined filter and quadrature phase shift can aggravate stability.

This is not usually a problem, but should be kept in mind.

Quadrature Detector

Figure 7 shows an equivalent circuit of the SA614A quadrature

detector. It is a multiplier cell similar to a mixer stage. Instead of

mixing two different frequencies, it mixes two signals of common

frequency but different phase. Internal to the device, a constant

amplitude (limited) signal is differentially applied to the lower port of

the multiplier. The same signal is applied single-ended to an

external capacitor at Pin 9. There is a 90 phase shift across the

plates of this capacitor, with the phase shifted signal applied to the

upper port of the multiplier at Pin 8. A quadrature tank (parallel L/C

network) permits frequency selective phase shifting at the IF

frequency. This quadrature tank must be returned to ground through

a DC blocking capacitor.

The loaded Q of the quadrature tank impacts three fundamental

aspects of the detector: Distortion, maximum modulated peak

deviation, and audio output amplitude. Typical quadrature curves

are illustrated in Figure 12. The phase angle translates to a shift in

the multiplier output voltage.

Thus a small deviation gives a large output with a high Q tank.

However, as the deviation from resonance increases, the

non-linearity of the curve increases (distortion), and, with too much

deviation, the signal will be outside the quadrature region (limiting

the peak deviation which can be demodulated). If the same peak

deviation is applied to a lower Q tank, the deviation will remain in a

region of the curve which is more linear (less distortion), but creates

a smaller phase angle (smaller output amplitude). Thus the Q of the

quadrature tank must be tailored to the design. Basic equations and

an example for determining Q are shown below. This explanation

includes first-order effects only.

Frequency Discriminator Design Equations for

SA614A

where

+ C

= R (C

L(C

1 +

+ C

)

Figure 11.

)

( )

(1a)

(1b)

(1c)

SR00333

OUT

Product specification

SA614A

SA614AD/01,112 NXP Semiconductors, SA614AD/01,112 Datasheet - Page 9

SA614AD/01,112

Specifications of SA614AD/01,112

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