AD8309ARUZ Datasheet AD8309ARUZ, AD8309ARU, AD8309ARU-REEL7 | P7-P9

REV. B

AD8309

–7–

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

OUT

= V

log (V

) (1)

where V

is the “slope voltage.” V

is the input voltage, and V

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

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

case V

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

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

and V

, that

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

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

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

resenting the behavior of a demodulating log amp such as the

AD8309, where V

has an alternating sign. However, the basic

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

= V

and becomes

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

straight line describing V

OUT

for all values of V

would con-

tinue indefinitely in both directions. The dotted line shows that

the effect of adding an offset voltage V

SHIFT

to the output is to

lower the effective intercept voltage V

OUT

–2V

OUT

= 0

LOG V

SHIFT

LOWER INTERCEPT

= 10

–2

–40dBc

= 10

+40dBc

= 10

+80dBc

= V

0dBc

Figure 19. Ideal Log Amp Function

Exactly the same modification could be achieved raising the gain

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

SHIFT

For example, if V

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

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

OUT

/DV

is a

very strong function of the instantaneous value of V

, as is

apparent by calculating the derivative. For the case where the

logarithmic base is e, it is easy to show that

∆

OUT

(2)

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.

REV. B

AD8309

–8–

As a consequence of this high gain, even very small amounts of

thermal noise at the input of a log amp will cause a finite output

for zero input, resulting in the response line curving away from

the ideal (Figure 19) at small inputs, toward a fixed baseline.

This can either be above or below the intercept, depending on

the design. Note that the value specified for this intercept is

invariably an extrapolated one: the RSSI output voltage will never

attain a value of exactly zero in a single supply implementation.

Voltage (dBV) and Power (dBm) Response

While Equation 1 is fundamentally correct, a simpler formula is

appropriate for specifying the RSSI calibration attributes of a

log amp like the AD8309, which demodulates an RF input. The

usual measure is input power:

OUT

= V

SLOPE

– P

) (3)

OUT

is the demodulated and filtered RSSI output, V

SLOPE

is the

logarithmic slope, expressed in volts/dB, P

is the input power,

expressed in decibels relative to some reference power level and

is the logarithmic intercept, expressed in decibels relative to

the same reference level.

The most widely used convention in RF systems is to specify

power in decibels above 1 mW in 50 Ω, written dBm. (However,

that the quantity [P

– P

] is simply dB). The logarithmic

function disappears from this formula because the conversion

has already been implicitly performed in stating the input in

decibels.

Specification of log amp input level in terms of power is strictly

a concession to popular convention: they do not respond to

power (tacitly “power absorbed at the input”), but to the input

voltage. In this connection, note that the input impedance of the

AD8309 is much higher that 50 Ω, allowing the use of an im-

pedance transformer at the input to raise the sensitivity, by up

to 13 dB.

The use of dBV, defined as decibels with respect to a 1 V rms sine

amplitude, is more precise, although this is still not unambiguous

complete as a general metric, because waveform is also involved

in the response of a log amp, which, for a complex input (such

as a CDMA signal) will not follow the rms value exactly. Since

most users specify RF signals in terms of power—more specifi-

cally, in dBm/50 Ω—we use both dBV and dBm in specifying

the performance of the AD8309, showing equivalent dBm levels

for the special case of a 50 Ω environment.

Progressive Compression

High speed, high dynamic range log amps use a cascade of

nonlinear amplifier cells (Figure 20) to generate the logarithmic

function from a series of contiguous segments, a type of piece-

wise-linear technique. This basic topology offers enormous gain-

bandwidth products. For example, the AD8309 employs in its

main signal path six cells each having a small-signal gain of

12.04 dB (×4) and a –3 dB bandwidth of 850 MHz, followed by

a final limiter stage whose gain is typically 18 dB. The overall

gain is thus 100,000 (100 dB) and the bandwidth to –10 dB

point at the limiter output is 525 MHz. This very high gain-

bandwidth product (52,500 GHz) is an essential prerequisite to

accurate operation under small signal conditions and at high

frequencies: Equation (2) reminds us that the incremental gain

decreases rapidly as V

increases. The AD8309 exhibits a loga-

rithmic response over most of the range from the noise floor of

–91 dBV, or 28 µV rms, (or –78 dBm/50 Ω) to a breakdown-

limited peak input of 4 V (requiring a balanced drive at the

differential inputs INHI and INLO).

STAGE 1 STAGE 2 STAGE N –1 STAGE N

A A A

Figure 20. Cascade of Nonlinear Gain Cells

Theory of Logarithmic Amplifiers

To develop the theory, we will first consider a somewhat differ-

ent scheme to that employed in the AD8309, but which is sim-

pler to explain, and mathematically more straightforward to

analyze. This approach is based on a nonlinear amplifier unit,

which we may call an A/1 cell, having the transfer characteristic

shown in Figure 21. We here use lowercase variables to define

the local inputs and outputs of these cells, reserving uppercase

for external signals.

The small signal gain ∆V

OUT

/∆V

is A, and is maintained for

inputs up to the knee voltage E

, above which the incremental

gain drops to unity. The function is symmetrical: the same drop

in gain occurs for instantaneous values of V

less than –E

The large signal gain has a value of A for inputs in the range

–E

< +E

, but falls asymptotically toward unity for very

large inputs.

In logarithmic amplifiers based on this simple function, both the

slope voltage and the intercept voltage must be traceable to the

one reference voltage, E

. Therefore, in this fundamental analy-

sis, the calibration accuracy of the log amp is dependent solely on

this voltage. In practice, it is possible to separate the basic refer-

ences used to determine V

and V

. In the AD8309, V

is trace-

able to an on-chip band-gap reference, while V

is derived from

the thermal voltage kT/q and later temperature-corrected by a

precise means.

Let the input of an N-cell cascade be V

, and the final output

OUT

. For small signals, the overall gain is simply A

. A six-

stage system in which A = 5 (14 dB) has an overall gain of

15,625 (84 dB). The importance of a very high small-signal ac

gain in implementing the logarithmic function has already been

noted. However, this is a parameter of only incidental interest in

the design of log amps; greater emphasis needs to be placed on

the nonlinear behavior.

SLOPE = A

SLOPE = 1

OUTPUT

INPUT

A/1

Figure 21. The A/1 Amplifier Function

Thus, rather than considering gain, we will analyze the overall

nonlinear behavior of the cascade in response to a simple dc

input, corresponding to the V

of Equation (1). For very small

inputs, the output from the first cell is V

= AV

; from the

second, V

= A

, and so on, up to V

= A

. At a certain

value of V

, the input to the Nth cell, V

N–1

, is exactly equal to

the knee voltage E

. Thus, V

OUT

= AE

and since there are N–1

cells of gain A ahead of this node, we can calculate that V

N–1

. This unique point corresponds to the lin-log transition,

REV. B

AD8309

–9–

labeled ① on Figure 22. Below this input, the cascade of gain

cells is acting as a simple linear amplifier, while for higher values

of V

, it enters into a series of segments which lie on a logarith-

mic approximation.

Continuing this analysis, we find that the next transition occurs

when the input to the (N–1)th stage just reaches E

, that is,

when V

= E

N–2

. The output of this stage is then exactly

. It is easily demonstrated (from the function shown in

Figure 21) that the output of the final stage is (2A–1)E

(la-

beled ≠ on Figure 22). Thus, the output has changed by an

amount (A–1)E

for a change in V

from E

N–1

to E

N–2

that is, a ratio change of A.

OUT

LOG V

RATIO

OF A

N–1

N–2

N–3

N–4

(A-1) E

(4A-3) E

(3A-2) E

(2A-1) E

Figure 22. The First Three Transitions

At the next critical point, labeled ③, the input is A times larger

and V

OUT

has increased to (3A–2)E

, that is, by another linear

increment of (A–1)E

. Further analysis shows that, right up to

the point where the input to the first cell reaches the knee volt-

age, V

OUT

changes by (A–1)E

for a ratio change of A in V

Expressed as a certain fraction of a decade, this is simply log

(A).

For example, when A = 5 a transition in the piecewise linear

output function occurs at regular intervals of 0.7 decade (log10(A),

or 14 dB divided by 20 dB). This insight allows us to immedi-

ately state the “Volts per Decade” scaling parameter, which is

also the “Scaling Voltage” V

when using base-10 logarithms:

Linear Change inV

Decades Change inV

OUT

( –)

log ( )

(4)

Note that only two design parameters are involved in determin-

ing V

, namely, the cell gain A and the knee voltage E

, while

N, the number of stages, is unimportant in setting the slope of

the overall function. For A = 5 and E

= 100 mV, the slope

would be a rather awkward 572.3 mV per decade (28.6 mV/dB).

A well designed practical log amp will provide more rational

scaling parameters.

The intercept voltage can be determined by solving Equation

(4) for any two pairs of transition points on the output function

(see Figure 22). The result is:

+(/[–])11

(5)

For the example under consideration, using N = 6, V

evaluates

to 4.28 µV, which thus far in this analysis is still a simple dc

voltage.

A/0

SLOPE = 0

SLOPE = A

OUTPUT

INPUT

Figure 23. A/0 Amplifier Functions (Ideal and tanh)

Care is needed in the interpretation of this parameter. It was

earlier defined as the input voltage at which the output passes

through zero (see Figure 19). Clearly, in the absence of noise

and offsets, the output of the amplifier chain shown in Figure 20

can only be zero when V

= 0. This anomaly is due to the finite

gain of the cascaded amplifier, which results in a failure to main-

tain the logarithmic approximation below the “lin-log transition”

(Point ① in Figure 22). Closer analysis shows that the voltage

given by Equation (5) represents the extrapolated, rather than

actual, intercept.

Demodulating Log Amps

Log amps based on a cascade of A/1 cells are useful in baseband

(pulse) applications, because they do not demodulate their input

signal. Demodulating (detecting) log-limiting amplifiers such as

the AD8309 use a different type of amplifier stage, which we

will call an A/0 cell. Its function differs from that of the A/1 cell

in that the gain above the knee voltage E

falls to zero, as shown

by the solid line in Figure 23. This is also known as the limiter

function, and a chain of N such cells is often used alone to

generate a hard limited output, in recovering the signal in FM

and PM modes.

The AD640, AD606, AD608, AD8307, AD8309, AD8313 and

other Analog Devices communications products incorporating a

logarithmic IF amplifier all use this technique. It will be appar-

ent that the output of the last stage cannot now provide a loga-

rithmic output, since this remains unchanged for all inputs

above the limiting threshold, which occurs at V

= E

N–1

Instead, the logarithmic output is generated by summing the

outputs of all the stages. The full analysis for this type of log amp

is only slightly more complicated than that of the previous case.

It can be shown that, for practical purpose, the intercept voltage

is identical to that given in Equation (5), while the slope

voltage is:

log ( )

(6)

An A/0 cell can be very simple. In the AD8309 it is based on a

bipolar-transistor differential pair, having resistive loads R

and

an emitter current source I

. This amplifier limiter cell exhibits

an equivalent knee-voltage of E

= 2kT/q and a small-signal

gain of A = I

. The large signal transfer function is the

hyperbolic tangent (see dotted line in Figure 23). This function

is very precise, and the deviation from an ideal A/0 form is not

detrimental. In fact, the “rounded shoulders” of the tanh func-

tion beneficially result in a lower ripple in the logarithmic con-

formance than that which would be obtained using an ideal A/0

function. A practical amplifier chain built of these cells is differ-

ential in structure from input to final output, and has a low

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Logarithmic Amplifiers 5-500 MHz 100 dB w/ Limiter Output

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