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SA5212A

Transimpedance amplifier (140MHz)

Philips Electronics 

Philips Semiconductors

Transimpedance amplifier (140MHz)

Product specification

SA5212A

VCC1

R1

R3

R12

VCC2

R13

INPUT

Q2

Q4

Q1

Q3

+

PHOTODIODE

R2

GND1

Q15

R14

R7

R5

R4

Q16

R15

VB2

Q11

Q12

OUT–

+

OUT+

GND2

SD00328

Figure 11. Transimpedance Amplifier

R1

IC1

INPUT

IB

IIN

Q1

VIN

IF

VCC

R3

Q2

R2

Q3

VEQ3

RF

R4

SD00329

Figure 12. Shunt-Series Input Stage

DYNAMIC RANGE

The electrical dynamic range can be defined as the ratio of

maximum input current to the peak noise current:

Electrical dynamic range, DE, in a 200MHz bandwidth assuming

IINMAX = 120µA and a wideband noise of IEQ=52nARMS for an

external source capacitance of CS = 1pF.

DE

+

(Max.

(Peak

input current)

noise current)

DE(dB)

+

20

log

(120

(Ǹ2

@ 10*6)

52nA)

DE(dB)

+

(120mA)

20 log (73nA)

+ 64dB

In order to calculate the optical dynamic range the incident optical

power must be considered.

For a given wavelength λ;

Energy of one Photon = hc watt sec (Joule)

l

Where h=Planck’s Constant = 6.6 × 10-34 Joule sec.

c = speed of light = 3 × 108 m/sec

c / λ = optical frequency

No. of incident photons/sec= where P=optical incident power

P

No. of incident photons/sec = hc

l

where P = optical incident power

P

No. of generated electrons/sec =

h

@

hc

l

where η = quantum efficiency

+

no.

of

generated electron hole

no. of incident photons

paris

P

NI

+

h

@

hc

l

@

e

Amps

(Coulombsńsec.)

where e = electron charge = 1.6 × 10-19 Coulombs

h@e

Responsivity R = hc Amp/watt

l

I + P@R

Assuming a data rate of 400 Mbaud (Bandwidth, B=200MHz), the

noise parameter Z may be calculated as:1

ǒ Ǔ Z

+

IEQ

qB

+

(1.6

@

52 @ 10*9

10*19)(200

@

106)

+

1625

Amp

Amp

where Z is the ratio of RMS noise output to the peak response to a

single hole-electron pair. Assuming 100% photodetector quantum

efficiency, half mark/half space digital transmission, 850nm

lightwave and using Gaussian approximation, the minimum required

optical power to achieve 10-9 BER is:

PavMIN +

12

hc

l

B

Z

+

12

(2.3 @ 10*19)

200 @ 106 1625 + 897nW + * 30.5dBm,

where h is Planck’s Constant, c is the speed of light, λ is the

wavelength. The minimum input current to the SA5212A, at this

input power is:

IavMIN

+

qPavMIN

l

hc

+

897 @ 10*9 @ 1.6 @ 10*19

2.3 @ 10*19

= 624nA

1998 Oct 07

12

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