AD8309ARUZ Analog Devices Inc, AD8309ARUZ Datasheet - Page 7

AD8309ARUZ

Manufacturer Part Number

AD8309ARUZ

Description

IC LOGARITHM AMP 100DB 16-TSSOP

Manufacturer

Analog Devices Inc

Type

Logarithmic Amplifierr

Datasheets

1.AD8309ARUZ.pdf (20 pages)

2.AD8309ARUZ.pdf (4 pages)

Specifications of AD8309ARUZ

Applications

Receiver Signal Strength Indication (RSSI)

Mounting Type

Surface Mount

Package / Case

16-TSSOP

No. Of Amplifiers

Dynamic Range, Decades

Scale Factor V / Decade

0.4

Response Time

67ns

Supply Voltage Range

2.7V To 6.5V

Amplifier Case Style

TSSOP

No. Of Pins

Supply Current

16mA

Amplifier Type

Logarithmic

Bandwidth

500 MHz

Current, Output

1 mA

Current, Supply

16 mA

Impedance, Thermal

150 °C/W

Number Of Amplifiers

Single

Package Type

TSSOP-16

Power Dissipation

500 mW

Resistance, Input

1000 Ohms

Temperature, Operating, Range

-40 to +85 °C

Time, Fall

0.4 ns

Time, Rise

0.4 ns

Voltage, Noise

1.28 nV/sqrt Hz

Voltage, Supply

2.7 to 6.5 V

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

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THEORY OF OPERATION

The AD8309 is an advanced IF signal processing IC, intended

for use in high performance receivers, combining two key func-

tions. First, it provides a large voltage gain combined with pro-

gressive compression, through which an IF signal of high dynamic

range is converted into a square-wave (that is, hard limited)

output, from which frequency and phase information modulated

on this input can be recovered by subsequent signal processing.

For this purpose, the noise level referred to the input must be

very low, since it determines the detection threshold for the receiver.

Further, it is often important that the group delay in this ampli-

fier be essentially independent of the signal level, to minimize

the risk of amplitude-to-phase conversion. Finally, it is also desir-

able that the amplitude of the limited output be well defined and

temperature stable. In the AD8309, this amplitude can be con-

trolled by the user, or even completely shut off, providing greater

flexibility.

The second function is to provide a demodulated (baseband)

output proportional to the decibel value of the signal input,

which may be used to measure the signal strength. This output,

which typically runs from a value close to the ground level to a

few volts above ground, is called the Received Signal Strength

Indication, or RSSI. The provision of this function requires the

use of a logarithmic amplifier (log amp). For this output to be

suitable for measuring signal strength, it is important that its

scaling attributes are well controlled.

These are the logarithmic slope, specified in mV/dB, and the

intercept, often specified as an equivalent power level at the

amplifier input, although a log amp is inherently a voltage-

responding device. (See further discussion, below). Also

important is the law conformance, that is, how well the RSSI

approximates an ideal function. Many low quality log amps

provide only an approximate solution, resulting in large errors in

law conformance and scaling. All Analog Devices log amps are

designed with close attention to matters affecting accuracy of

the overall function.

In the AD8309, these two basic signal-processing functions are

combined to provide the necessary voltage gain with progressive

compression and hard limiting, and the determination of the

logarithmic magnitude of the input (RSSI). This combination is

called a log limiting amplifier. A good grasp of how this product

works will avoid many pitfalls in their application.

Log-Amp Fundamentals

The essential purpose of a logarithmic amplifier is to reduce a

signal of wide dynamic range to its decibel equivalent. It is thus

primarily a measurement device. The logarithmic representation

leads to situations that may be confusing or even paradoxical.

For example, a voltage offset added to the RSSI output of a log

amp is equivalent to a gain increase ahead of its input.

When all the variables expressed as voltages, then, regardless of

the particular structure, the output can be expressed as

where V

is the “intercept voltage.” The logarithm is usually to base-10,

which is appropriate to a decibel-calibrated device, in which

case V

(1) that a log amp requires two references, here V

determine the scaling of the circuit. The absolute accuracy of a

log amp cannot be any better than the accuracy of its scaling

REV. B

OUT

is also the “volts-per-decade.” It will be apparent from

is the “slope voltage.” V

= V

log (V

)

is the input voltage, and V

and V

, that

(1)

–7–

references. Note that (1) is mathematically incomplete in rep-

resenting the behavior of a demodulating log amp such as the

AD8309, where V

principles are unaffected.

Figure 19 shows the input/output relationship of an ideal log

amp, conforming to Equation (1). The horizontal scale is loga-

rithmic, and spans a very wide dynamic range, shown here as

over 120 dB, that is, six decades of voltage or twelve decades of

input-referred power. The output passes through zero (the

“log-intercept”) at the unique value V

negative for inputs below the intercept. In the ideal case, the

straight line describing V

tinue indefinitely in both directions. The dotted line shows that

the effect of adding an offset voltage V

lower the effective intercept voltage V

Exactly the same modification could be achieved raising the gain

(or signal level) ahead of the log amp by the factor V

For example, if V

the AD8309), an offset of 120 mV added to the output will

appear to lower the intercept by two tenths of a decade, or 6 dB.

Adding an offset to the output is thus indistinguishable from

applying an input level that is 6 dB higher.

The log amp function described by (1) differs from that of a

linear amplifier in that the incremental gain DV

very strong function of the instantaneous value of V

apparent by calculating the derivative. For the case where the

logarithmic base is e, it is easy to show that

That is, the incremental gain of a log amp is inversely propor-

tional to the instantaneous value of the input voltage. This re-

mains true for any logarithmic base. A “perfect” log amp would

be required to have infinite gain under classical “small-signal”

(zero-amplitude) conditions. This demonstrates that, whatever

means might be used to implement a log amp, accurate HF

response under small signal conditions (that is, at the lower end

of the full dynamic range) demands the provision of a very high

gain-bandwidth product. A wideband log amp must therefore use

many cascaded gain cells each of low gain but high bandwidth.

For the AD8309, the gain-bandwidth (–10 dB) product is

52,500 GHz.

OUT

–2V

OUT

= 0

–40dBc

OUT

= 10

–2

Figure 19. Ideal Log Amp Function

LOWER INTERCEPT

is 400 mV/decade (that is, 20 mV/dB, as for

has an alternating sign. However, the basic

0dBc

= V

OUT

for all values of V

+40dBc

SHIFT

= 10

SHIFT

= V

to the output is to

and becomes

+80dBc

OUT

AD8309

= 10

would con-

/DV

SHIFT

, as is

LOG V

is a

(2)

AD8309ARUZ Analog Devices Inc, AD8309ARUZ Datasheet - Page 7

AD8309ARUZ

Specifications of AD8309ARUZ

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