I have come up with a solution which works pretty well, following the suggestions in the comments. Particularly, @X-Zero's suggestion of creating a table of Soundexes: In my case, I can create new tables, but altering the existing schema is not allowed!
So, my process is as follows:
Create a new table with columns:
position; with the primary key over (
position) and an additional index over (
Go through each person in the biographical table:
Concatenate their forename and surname.
Change the codepage to
us7ascii, so accented characters are normalised. This is because the Soundex algorithm doesn't work with accented characters.
Convert all non-alphabetic characters into whitespace and consider this the boundary between tokens.
Tokenise this string and insert into the table the token (in lowercase), the Soundex of the token and the position the token comes in the original string; associate this with
cursor myNames is
forename||' '||surname person_name
for person in myNames
nameString := trim(
posn := 1;
while nameString is not null
token := substr(nameString,1,instr(nameString,' ') - 1);
insert into personsearch values (person.id,lower(token),soundex(token),posn);
nameString := substr(nameString,instr(nameString,' ') + 1);
posn := posn + 1;
So, for example, "Siân O'Conner" gets tokenised into "sian" (position 1), "o" (position 2) and "conner" (position 3) and those three entries, with their Soundex, get inserted into
personsearch along with their ID.
- To search, we do the same process: tokenise the search criteria and then return results where the Soundexes and relative positions match. We order by the position and then the Levenshtein distance (
ld) from the original search for each token, in turn.
This query, for example, will search against two tokens (i.e., pre-tokenised search string):
with searchcriteria as (
select 'john' token1,
from peoplesearch alpha
on mypeople.student_id = alpha.student_id
join peoplesearch beta
on beta.student_id = alpha.student_id
and beta.position > alpha.position
on 1 = 1
where alpha.sound = soundex(searchcriteria.token1)
and beta.sound = soundex(searchcriteria.token2)
order by alpha.position,
To search against an arbitrary number of tokens, we would need to use dynamic SQL: joining the search table as many times as there are tokens, where the
position field in the joined table must be greater than the
position of the previously joined table... I plan to write a function to do this -- as well as the search string tokenisation -- which will return a table of IDs. However, I just post this here so you get the idea :)
As I say, this works pretty well: It returns good results pretty quickly. Even searching for "John Smith", once cached by the server, runs in less than 0.2s; returning over 200 rows... I'm pretty pleased with it and will be looking to put it into production. The only issues are:
The precalculation of tokens takes a while, but it's a one-off process, so not too much of a problem. A related problem however is that a trigger needs to be put on the
mypeople table to insert/update/delete tokens into the search table whenever the corresponding operation is performed on
mypeople. This may slow up the system; but as this should only happen during a few periods in a year, perhaps a better solution would be to rebuild the search table on a scheduled basis.
No stemming is being done, so the Soundex algorithm only matches on full tokens. For example, a search for "chris" will not return any "christopher"s. A possible solution to this is to only store the Soundex of the stem of the token, but calculating the stem is not a simple problem! This will be a future upgrade, possibly using the hyphenation engine used by TeX...
Anyway, hope that helps :) Comments welcome!
EDIT My full solution (write up and implementation) is now here, using Metaphone and the Damerau-Levenshtein Distance.