Treatment of Uncertainties for National Estimates of Greenhouse Gas Emissions

A4 References

Table A1. Example Output from a Qualitative Uncertainty Analysis of an Emissions Inventory

Inventory Component	Basis of Uncertainty	Description (examples only)
Survey	Survey respondent expertise	Incorrect or incomplete answers could result because of lack of understanding or incorrect interpretation
	Unknown answers	Some equipment is very old, some has been modified, hence manufacturers' ratings would be no longer applicable
	Incorrect responses	Some respondents did not read instructions. Confusion over units.
	Data entry	Typographical and data omission errors possible. Transcription by support staff?
	Omitted sources	x% of companies did not return survey results. Some returns incomplete.
Emissions methodology	Emission factors	Emission factors represent an average. Results could be biased by distribution of responses.
	Fugitive emissions	Calculated using an empirical formula. Assumptions therein may not be valid in all cases.
	Applicability/usage	A more applicable emissions methodology could exist. Methodology could have been applied incorrectly because of an incorrect assumption.

Table A2. AP-42 Rating System for Emissions Test Data

Rating	Description
A	Tests are performed by a sound methodology and are reported in sufficient detail for adequate validation
B	Tests are performed by a sound methodology, but lacking sufficient detail for adequate validation
C	Tests are based on an unproven or new methodology, or are lacking a significant amount of background information
D	Tests are based on a generally unacceptable method, but the method may provide an order-of-magnitude value for the source

Table A3. AP-42 Rating System for Emission Factors

Rating	Quality Rating	Discussion
A	Excellent	Factor is developed from A and B-rated source test data taken from many randomly chosen facilities in the industry population. The source category population is sufficiently specific to minimise variability.
B	Above average	Factor is developed from A or B-rated test data from a 'reasonable number' of facilities. Although no specific bias is evident, it is not clear if the facilities tested represent a random sample of the industry. As with an A rating, the source category population is sufficiently specific to minimise variability.
C	Average	Factor is developed from A, B and/or C-rated test data from a reasonable number of facilities. Although no specific bias is evident, it is not clear if the facilities tested represent a random sample of the industry. As with the A-rating, the source category population is sufficiently specific to minimise variability.
D	Below average	Factor is developed from A, B and/or C-rated test data from a small number of facilities, and there may be reason to suspect that these facilities do not represent a random sample of the industry. There also may be evidence of variability within the source population.
E	Poor	Factor is developed from C or D-rated test data, and there may be reason to suspect that the facilities tested do not represent a random sample of the industry. There also may be evidence of variability within the source category population.

Table A4. Guidelines Proposed for Emissions Factors
Ratings in the UK

Rating	Description
A	An estimate based on a large number of measurements made at a large number of facilities that fully represent the sector
B	An estimate based on a large number of measurements made at a large number of facilities that represent a large part of the sector
C	An estimate based on a number of measurements made at a small number of representative facilities, or an engineering judgement based on a number of relevant facts
D	An estimate based on a single measurement or an engineering calculation derived from a number of relevant facts and some assumptions
E	An estimate based on an engineering calculation derived from assumptions only

Table A5. Protocol for Combining Quality Ratings for
Emission Factors and Activity Rates

Combination Factor	Final Factor	Combination Factor	Final Factor
E - E	E	C - C	C
E - D	D	D - A	C
E - C	D	C - B	B
D - D	D	C - A	B
E - B	D	B - B	B
E - A	C	B - A	A
D - C	C	A - A	A
D - B	C

Table A6. Data Quality Codes Recommended by the IPCC

	Estimates		Quality		Documentation		Disaggregation
Code	Meaning	Code	Meaning	Code	Meaning	Code	Meaning
Part	Partly estimated	H	High confidence in estimation	H	High (all background information included)	1	Total emissions estimated
All	Full estimate of all possible sources	M	Medium confidence in estimation	M	Medium (some background information included)	2	Sectoral split
NE	Not estimated	L	Low confidence in estimation	L	Low (only emission estimates included)	3	Sub-sectoral split
IE	Estimated but included elsewhere
NO	Not occurring
NA	Not applicable

Table A7. Data Attribute Rating System: How Scores are Evaluated
for an Emission Inventory

Attribute	Emission factor	Activity rate	Emissions
Measurement/method	e₁\|	a₁\|	e₁\| X a₁\|
Source specificity	e₂\|	a₂\|	e₂\| X a₂\|
Spatial allocation	e₃\|	a₃\|	e₃\| X a₃\|
Temporal Allocation	e₄\|	a₄\|	e₄\| X a₁4
Composite Score	S^⁴_i=1 e_i ___ 4	S^⁴_i=1 a_i ___ 4	S^⁴_i=1 e_i x a_i ______ 4

Table A8. Summary of Methods for Assessing Uncertainties in Emissions Estimates or Evaluating Data Quality

Method	Advantages	Disadvantages	Utility/Relevance
Qualitative	low cost comprehensive	subjective limited value of output	useful only for screening and prioritisation
Semi-quantitative/ Data Quality Ranking	moderate cost comprehensive documented and structured approaches available useful in prioritising areas for further quantitative study	subjective (but less so than above) output still not fully quantitative, hence intercomparisons, etc., difficult	select the most appropriate tool (e.g. DARS, IPCC scoring) use as basis for a more quantitative analysis in particular areas of the UK emissions database
Quantitative:
1. Expert estimation	moderate cost	requires considerable active participation from a wide range of experts owing to lack of information, cannot be used for large areas of emissions database	not suited to present study
2. Error propagation	not computationally complex	unless database structured appropriately, considerable cost unable to produce meaningful estimates if : parameter values are correlated or uncertainty exceeds a critical magnitude owing to lack of information, cannot be used for large areas of emissions database difficult to interface with less quantitative methods	in the context of this study, does not have any advantages over the following technique
3. Direct simulation	can accommodate large parameter uncertainties and correlations between parameter values allows most important component sources of uncertainty to be identified	unless database structured appropriately, considerable cost considerable care required to evaluate output distributions (emissions estimates) owing to lack of information, cannot be used for large areas of emissions database difficult to interface with less quantitative methods	set up probabilistic framework for areas of database amenable to quantitative analysis (i.e. those sections for which quantitative information is available)